CN1955218A - Preparation method of ultraviolet light stabilizer - Google Patents
Preparation method of ultraviolet light stabilizer Download PDFInfo
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- CN1955218A CN1955218A CN 200610022132 CN200610022132A CN1955218A CN 1955218 A CN1955218 A CN 1955218A CN 200610022132 CN200610022132 CN 200610022132 CN 200610022132 A CN200610022132 A CN 200610022132A CN 1955218 A CN1955218 A CN 1955218A
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- tio
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Abstract
This invention relates to a preparation of ultraviolet light stability agent, its characteristic is that after 1-20 weight shares of nanometer TiO2 particle that surface modified by coupling agent and 40-60 weight shares of emulsifying agent solution of which density is 0.5-3wt% are mixed uniformly, disperse 3-10 minutes in supersonic wave(frequency: 19-21KHz,power: 50-250W), then the mixed liquor is added into three-necked bottle that has agitator, thermometer and reflux condenset, it is protected by nitrogen gas, add 5-10 weight shares of initiator solution of which density is 0.5-3wt% when the temperature is 50-80DEG C, continuously dropwise 10-54 weight shares of acrylics monomer, after monomer has been dropwised they react 1-2 hours, reduce the temperature to release materials, filter, obtain ultraviolet light stabilizer-polyacrylic ester/ complex particle of nanometer TiO2 by drying. This ultraviolet light stabilizer and giant molecule material are mixed, ageing effect is accelerated by ultraviolet light, the test result indicates that it raises the bearing ultraviolet light stabilizer of this giant molecule material, meanwhile it raises mechanic function.
Description
Technical field
The present invention relates to a kind of preparation method of UV light stabilizing agent, belong to the polymer modification field.
Background technology
The macromolecular material raw material sources are abundant, and density is little, mechanics, electricity, excellent optical performance, and corrosion-resistant, forming process is easy, is used widely in many different occasions.Because the self structure characteristics, macromolecular material in use also exposes some shortcomings, and wherein particularly outstanding is easily aging.During the outdoor use of macromolecular material, under sun exposure, be subjected to the effect of irradiation of UV-light, more or less all photooxidation resistance can take place, cause structure deteriorate, performance degradation, so that afunction.In order to prolong the work-ing life of macromolecular material, many scholars are devoted to the research of this respect always.Photostabilised method to macromolecular material mainly contains two macrospecies, a kind of is the structure that changes polymkeric substance, synthetic polymkeric substance with height light stability structure comprises the clean method for making of polymkeric substance, between polymerization period or in the grafting process in the later stage, adds or connect the method for stablizer; Another kind is the method for adding various photostabilizers.What generally adopt at present is second method.The photooxidation resistance modification of macromolecular material mainly realizes (K Takaya, S Kono, United States Patent, 5,294,661,1994 by adding auxiliary agent modes such as benzophenone, benzotriazole or triazine; Zhong Shiyun, volumes such as Xu Qianwei, " polymer degradation and stabilization ", Beijing: Chemical Industry Press, 2002; S Kielhorb-Bayer, U Eichenauer Ger.Offen.DE 4442167 A1,1996), but these organic photostabilizers can make the mechanical property of macromolecular material reduce (T Katsumata, United States Patent, 5,086,095,1992).
Nano-ZnO, TiO as photomask agent
2Particle is in the application of the fast light oxygen aging performance of macromolecular material, and pertinent literature has some reports, nano-ZnO, nano-TiO
2The ultravioletlight screening ability that particle is strong has obtained everybody approval (T Kyprianidou-Leodidou, P Margraf, Polym Adv Technol, 1997,8,505~512; C ASmith, J L Gerlock, et al, Polym Degrad Stab, 2001,72,89~97; A Ammala, A J Hill, J NanoparticleResearch 2002,4,167~174; D K Hwang, J H Moon, J Sol-Gel Sci Technol, 2003,26,783~787; R Robert, J R Farrar, BioControl 2003,48, and 543~560; R J Nussbaumer, W R Caseri, MacromolMater Eng, 2003,288,44~49; K Q Han, M H Yu, J Appl Polym Sci, 2006,100,1588~1593).But because the inorganic nano-particle specific surface area is big, the surface energy height be very easy between the particle agglomeration takes place, and the interface compatibility of inorganic nano-particle and polymeric matrix is poor, inorganic particulate is difficult to be dispersed in the polymeric matrix, thereby does not often reach intended purposes.We are by molecular designing, at nano-TiO
2Acrylic ester polymer in the particle surface grafting prepares a kind of novel UV light stabilizing agent---polyacrylic ester/nano-TiO
2Composite particles, nano-TiO
2Particle self can absorb a large amount of UV-light, and UV-light is reduced to minimum level to the destruction of polymeric matrix; Shell polymkeric substance in the composite particles can improve nano-TiO
2Dispersiveness and the nano-TiO of particle in polymeric matrix
2Interfacial bonding property between particle and polymeric matrix; Polyacrylic ester/nano-TiO
2Composite particles can also play the effect that improves the polymeric matrix mechanical property.With prepared polyacrylic ester/nano-TiO
2Composite particles is applied in the aging modification of ultraviolet resistance of polymkeric substance, in the hope of solving nano-TiO
2Scattering problem and the nano-TiO of particle in polymeric matrix
2Bonding interface problem between particle and polymeric matrix, realize both having improved the fast light oxygen aging performance of polymeric matrix, strengthen polymeric matrix flexible dual purpose again, overcome general organic photostabilizer and improving the deficiency that the fast light oxygen aging performance of polymkeric substance reduces the polymeric matrix mechanical property simultaneously.
Summary of the invention
The objective of the invention is is the preparation method that a kind of UV light stabilizing agent is provided at the deficiencies in the prior art.Be characterized in by modified Nano TiO
2There is the in-situ emulsion polymerization of acrylic ester monomer down in particle, and preparation is based on the polyacrylic ester/nano-TiO of covalent bonds
2Composite particles; Another object of the present invention is that obtained composite particles is added in the macromolecular material matrix resin, improves the ultraviolet-resistant performance of macromolecular material.
Purpose of the present invention is realized that by following technical measures wherein said umber is parts by weight except that specified otherwise.
The preparation method of UV light stabilizing agent
Take by weighing nano-TiO by weight
210~30 parts on particle, 0.1~3 part of coupling agent, 70~90 parts of 95wt% ethanol, adding has in the three-necked bottle of agitator, thermometer and reflux exchanger, in 40~70 ℃ of temperature, stirs 0.5~6 hour, and drying obtains modified Nano TiO
2Particle; With modified Nano TiO
21~20 part on particle and concentration are after 40~60 parts of the emulsifier solutions of 0.5~3wt% stir; under ultrasonic wave, disperseed 3~10 minutes; ultrasonic frequency: 19~21KHz; power: 50~250W; then mixed solution is added and have agitator; in the three-necked bottle of thermometer and reflux exchanger; nitrogen protection; when 50~80 ℃ of temperature, add concentration and be 5~10 parts of the initiator solutions of 0.5~3wt%; the dropwise addition of acrylic acid esters monomer is 10~54 parts continuously; the intact afterreaction of monomer dropping 1~2 hour; cooling discharge filters, and drying obtains UV light stabilizing agent-polyacrylic ester/nano-TiO
2Composite particles.
Coupling agent is CH
2=C (R
1)-R
2-Si-(O-R
3)
3, wherein, R
1=H ,-CH
3Or-CH
2CH
3, R
2=0 ,-COO (CH
2)
3-, R
3=-CH
3,-CH
2CH
3
Acrylic ester monomer is at least a in methyl methacrylate, methyl acrylate, 2-EHA, butyl acrylate, butyl methacrylate or the ethyl propenoate monomer.
Emulsifying agent is any in dodecyl chlorination ammonium, sodium lauryl sulphate, Trombovar, the Sodium dodecylbenzene sulfonate.
Initiator is Potassium Persulphate, ammonium persulphate, isopropyl benzene hydroperoxide, Potassium Persulphate---in the iron protochloride any.
The UV light stabilizing agent that method for preparing obtains.
UV light stabilizing agent is used for the ultraviolet-resistant performance modification of macromolecular material.
Macromolecular material is polyoxymethylene, polycarbonate and polyvinyl chloride.
Polyacrylic ester/nano-TiO
2The structure of composite particles
Nano-TiO
2Particle and after the trichloromethane extracting polyacrylic acid/nano-TiO
2The FTIR analytical results of composite particles sees Fig. 1 for details.The result shows, at polyacrylic acid/nano-TiO
2Be not that simple physics is mixed between polyacrylic ester and the inorganic particulate in the composite particles, but be together with each other by chemical bond.
Polyacrylic acid/nano-TiO after the trichloromethane extracting
2The thermogravimetric analysis result of composite particles sees Fig. 2 for details.The result shows, polyacrylic ester and TiO in the composite particles
2Have strong chemical b ` between the particle, this strong chemical b ` has improved the thermostability of polyacrylic ester; The grafting efficiency of polymkeric substance can be up to more than 90% in the compound system.
Polyacrylic ester/nano-TiO
2The ultraviolet light performance of composite particles
Nano-TiO
2Particle, modified Nano TiO
2Particle and polyacrylic ester/nano-TiO
2The ultraviolet-visible diffuse reflection spectrum analytical results of composite particles sees Fig. 3 for details.The result shows, no matter nano-TiO
2Particle or modified Nano TiO
2Particle, or polyacrylic ester/nano-TiO
2Composite particles can shield the UV-light greater than 95% in 210~400nm UV wavelength range, have extremely strong ultravioletlight screening ability.
Polyacrylic ester/nano-TiO
2Oxygen aging performance that the composite particles modified polymer material is fast light
UV light stabilizing agent modified polyacetal of the present invention (POM) sample is as shown in table 1 through 500 hours forward and backward Mechanics Performance Testing results of ultraviolet light irradiation.The result shows, is better than unmodified POM, the organic photostabilizer UV327 of benzotriazole category modification POM and TiO through the comprehensive ultraviolet light performance of composite particles modification POM
2The ultraviolet light performance of modification POM.
UV light stabilizing agent modified polycarbonate of the present invention (PC) sample is as shown in table 2 through 200 hours forward and backward Mechanics Performance Testing results of ultraviolet light irradiation.The result shows that composite particles also can improve the notched Izod impact strength of PC to a certain extent except the ultraviolet light performance that can improve PC.
UV light stabilizing agent modified polyvinyl chloride of the present invention (PVC) sample is as shown in table 3 through 1000 hours forward and backward Mechanics Performance Testing results of ultraviolet light irradiation.The result shows that composite particles not only can improve the ultraviolet light performance of PVC, but also can improve the notched Izod impact strength of PVC to a great extent.
The present invention has following advantage:
1. polyacrylic ester/nano-TiO
2Nano-TiO in the composite particles
2Between particle and the polymkeric substance is to combine with the covalent linkage form, when polyacrylic ester/nano-TiO
2When composite particles mixes with polymeric matrix, nano-TiO
2Particle can evenly spread in the polymeric matrix, and is difficult for being separated with polymkeric substance.
2. polyacrylic ester/nano-TiO
2The molecular structure of the acrylic polymer in the composite particles has designability, has the different structure composite particles according to different polymeric matrix structure designs, improves nano-TiO
2Dispersiveness and the nano-TiO of particle in polymeric matrix
2Interface compatibility between particle and polymeric matrix.
3. composite particles both can improve the fast light oxygen aging performance of polymeric matrix, can strengthen polymeric matrix toughness again, had overcome the drawback of organic photostabilizer modified polymer material.
4. adopt emulsion polymerization to prepare polyacrylic ester/nano-TiO
2Composite particles, environmental protection, industrial technology are ripe relatively, realize industrialization easily.
Description of drawings
Fig. 1 is a nano-TiO
2Particle (a) and after the trichloromethane extracting polyacrylic ester/nano-TiO
2The FTIR spectrogram of composite particles (b).
Fig. 2 is the polyacrylic ester/nano-TiO after the trichloromethane extracting
2The thermal multigraph of composite particles.
Fig. 3 is a nano-TiO
2Particle, modified Nano TiO
2Particle and polyacrylic ester/nano-TiO
2The ultraviolet-visible of the composite particles spectrogram that diffuses.
Embodiment
Below by embodiment the present invention is specifically described; be necessary to be pointed out that at this this example only is used for the present invention is further specified; can not be interpreted as limiting the scope of the invention, the person skilled in the art in this field can make some nonessential improvement and adjustment according to the content of foregoing invention.
Embodiment 1:
Take by weighing nano-TiO
2Particle 10 grams, vinyltriethoxysilane coupling agent 0.1 gram, 95wt% ethanol 90 grams, adding has in the three-necked bottle of agitator, thermometer and reflux exchanger, is warming up to 40 ℃, stirs 0.5 hour, and drying obtains modified Nano TiO
2Particle; With modified Nano TiO
2Particle 1 gram and concentration are after dodecyl chlorination ammonium solution 40 grams of 0.5wt% stir; under ultrasonic wave, disperseed 3 minutes; ultrasonic frequency: 19KHz; power: 50W; then mixed solution is added and have in the three-necked bottle of agitator, thermometer and reflux exchanger; nitrogen protection; adding concentration when 50 ℃ of temperature is potassium persulfate solution 5 grams of 3wt%; drip methyl methacrylate monomer 54 grams continuously; sustained reaction was 1 hour after monomer dropping finished; cooling discharge filters, and drying obtains UV light stabilizing agent---polyacrylic ester/nano-TiO
2Composite particles.
Embodiment 2:
Take by weighing nano-TiO
2Particle 15 grams, vinyltrimethoxy silane coupling agent 1.5 grams, 95wt% ethanol 85 grams, adding has in the three-necked bottle of agitator, thermometer and reflux exchanger, is warming up to 50 ℃, stirs 3 hours, and drying obtains modified Nano TiO
2Particle; With modified Nano TiO
2Particle 5 grams and concentration are after sodium dodecyl sulfate solution 50 grams of 1.5wt% stir; under ultrasonic wave, disperseed 5 minutes; ultrasonic frequency: 20KHz; power: 150W; then mixed solution is added and have agitator; in the three-necked bottle of thermometer and reflux exchanger; nitrogen protection; adding concentration when 70 ℃ of temperature is ammonium persulfate solution 8 grams of 2wt%; drip mix monomer 37 grams of methyl methacrylate and butyl acrylate continuously; sustained reaction was 1.5 hours after monomer dropping finished; cooling discharge filters, and drying obtains UV light stabilizing agent---polyacrylic ester/nano-TiO
2Composite particles.
Embodiment 3:
Take by weighing nano-TiO
2Particle 30 grams, methacryloxypropyl trimethoxy coupling agent 3 grams, 95wt% ethanol 70 grams, adding has in the three-necked bottle of agitator, thermometer and reflux exchanger, is warming up to 70 ℃, stirs 6 hours, and drying obtains modified Nano TiO
2Particle; With modified Nano TiO
2Particle 20 grams and concentration are after Sodium dodecylbenzene sulfonate solution 60 grams of 3wt% stir; under ultrasonic wave, disperseed 10 minutes; ultrasonic frequency: 21KHz; power: 250W; then mixed solution is added and have agitator; in the three-necked bottle of thermometer and reflux exchanger; nitrogen protection; adding concentration when 80 ℃ of temperature is isopropyl benzene hydroperoxide solution 10 grams of 0.5wt%; dropwise addition of acrylic acid ethyl ester monomer 10 restrains continuously; sustained reaction was 2 hours after monomer dropping finished; cooling discharge filters, and drying obtains UV light stabilizing agent---polyacrylic ester/nano-TiO
2Composite particles.
Table 1 modified polyacetal (POM) sample is through 500 hours forward and backward mechanical properties of ultraviolet light irradiation
Sample | Tensile strength (MPa) | Elongation at break (%) | Notched Izod impact strength (kJ/m 2) | |||
Pre-irradiation | Behind the irradiation | Pre-irradiation | Behind the irradiation | Pre-irradiation | Behind the irradiation | |
POM POM/0.2%UV327 POM/3% composite particles POM/1% nano-TiO 2Particle | 63.06 59.90 58.71 60.97 | 60.41 59.63 58.47 60.82 | 49.58 48.12 66.66 52.31 | 26.52 41.06 55.60 40.72 | 5.81 5.85 5.92 5.77 | 2.00 3.38 4.58 3.65 |
Table 2 modified polycarbonate (PC) sample is through 200 hours forward and backward mechanical properties of ultraviolet light irradiation
Sample | Tensile strength (MPa) | Notched Izod impact strength (kJ/m 2) | ||
Pre-irradiation | Behind the irradiation | Pre-irradiation | Behind the irradiation | |
PC PC/3% composite particles PC/1% nano-TiO 2Particle | 64.84 64.46 66.09 | 63.33 63.36 64.53 | 9.27 14.57 8.76 | 8.40 13.98 8.08 |
Table 3 modified polyvinyl chloride (PVC) sample is through 1000 hours forward and backward mechanical properties of ultraviolet light irradiation
Sample | Tensile strength (MPa) | Elongation at break (%) | Notched Izod impact strength (kJ/m 2) | |||
Pre-irradiation | Behind the irradiation | Pre-irradiation | Behind the irradiation | Pre-irradiation | Behind the irradiation | |
PVC PVC/0.3%UV327 PVC/3% composite particles | 63.08 64.54 60.87 | 65.62 69.10 65.20 | 15.91 17.13 16.37 | 12.95 13.97 13.78 | 1.90 1.94 7.14 | 1.80 1.88 6.60 |
Claims (8)
1. UV light stabilizing agent preparation method is characterized in that:
Take by weighing nano-TiO by weight
210~30 parts on particle, 0.1~3 part of coupling agent, 70~90 parts of 95wt% ethanol, adding has in the three-necked bottle of agitator, thermometer and reflux exchanger, in 40~70 ℃ of temperature, stirs 0.5~6 hour, and drying obtains modified Nano TiO
2Particle; With modified Nano TiO
21~20 part on particle and concentration are after 40~60 parts of the emulsifier solutions of 0.5~3wt% stir; under ultrasonic wave, disperseed 3~10 minutes; ultrasonic frequency: 19~21KHz; power: 50~250W; then mixed solution is added and have agitator; in the three-necked bottle of thermometer and reflux exchanger; nitrogen protection; when 50~80 ℃ of temperature, add concentration and be 5~10 parts of the initiator solutions of 0.5~3wt%; the dropwise addition of acrylic acid esters monomer is 10~54 parts continuously; the intact afterreaction of monomer dropping 1~2 hour; cooling discharge filters, and drying obtains UV light stabilizing agent-polyacrylic ester/nano-TiO
2Composite particles.
2. the preparation method of UV light stabilizing agent according to claim 1 is characterized in that coupling agent is CH
2=C (R
1)-R
2-Si-(O-R
3)
3, wherein, R
1=H ,-CH
3Or-CH
2CH
3, R
2=O ,-COO (CH
2)
3-, R
3=-CH
3,-CH
2CH
3
3. the preparation method of UV light stabilizing agent according to claim 1 is characterized in that acrylic ester monomer is at least a in methyl methacrylate, methyl acrylate, 2-EHA, butyl acrylate, butyl methacrylate or the ethyl propenoate monomer.
4. the preparation method of UV light stabilizing agent according to claim 1 is characterized in that emulsifying agent is any in dodecyl chlorination ammonium, sodium lauryl sulphate, Trombovar, the Sodium dodecylbenzene sulfonate.
5. the preparation method of UV light stabilizing agent according to claim 1 is characterized in that initiator is any in Potassium Persulphate, ammonium persulphate, isopropyl benzene hydroperoxide, the Potassium Persulphate-sodium bisulfite.
6. the UV light stabilizing agent for preparing of method according to claim 1.
7. the UV light stabilizing agent for preparing as method as described in the claim 6 is used for the ultraviolet-resistant performance modification of macromolecular material.
8. be polyoxymethylene, polycarbonate and polyvinyl chloride as macromolecular material as described in the claim 7.
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CN100462379C CN100462379C (en) | 2009-02-18 |
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Cited By (3)
Publication number | Priority date | Publication date | Assignee | Title |
---|---|---|---|---|
CN106633574A (en) * | 2016-12-30 | 2017-05-10 | 华东理工大学 | Preparation method of special titanium dioxide for organic glass |
CN106699958A (en) * | 2016-12-30 | 2017-05-24 | 华东理工大学 | Method for polymerizing acrylate organic silicon on titanium dioxide surface |
CN110903545A (en) * | 2019-11-11 | 2020-03-24 | 国网山东省电力公司兰陵县供电公司 | Anti-aging acid-alkali-resistant cable material and preparation method thereof |
Family Cites Families (2)
Publication number | Priority date | Publication date | Assignee | Title |
---|---|---|---|---|
DE102004061985A1 (en) * | 2004-12-23 | 2006-07-06 | Rehau Ag + Co | TPV Alternative |
US7265176B2 (en) * | 2005-01-31 | 2007-09-04 | E. I. Du Pont De Nemours And Company | Composition comprising nanoparticle TiO2 and ethylene copolymer |
-
2006
- 2006-10-27 CN CNB200610022132XA patent/CN100462379C/en not_active Expired - Fee Related
Cited By (4)
Publication number | Priority date | Publication date | Assignee | Title |
---|---|---|---|---|
CN106633574A (en) * | 2016-12-30 | 2017-05-10 | 华东理工大学 | Preparation method of special titanium dioxide for organic glass |
CN106699958A (en) * | 2016-12-30 | 2017-05-24 | 华东理工大学 | Method for polymerizing acrylate organic silicon on titanium dioxide surface |
CN106699958B (en) * | 2016-12-30 | 2018-08-24 | 华东理工大学 | A method of it is polymerize in titanium dioxide surface with acrylate organosilicon |
CN110903545A (en) * | 2019-11-11 | 2020-03-24 | 国网山东省电力公司兰陵县供电公司 | Anti-aging acid-alkali-resistant cable material and preparation method thereof |
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