CN109337559B - Blue light/color change prevention dual-function coating optical material and preparation method thereof - Google Patents

Abstract

The double-function coating optical material comprises an optical substrate, a blue light prevention coating and a photochromic coating. The blue light prevention coating is doped with polyurethane/light absorbent/titanium oxide nano composite microspheres, the blue light prevention coating is of a three-layer composite core-shell structure, the inner core is titanium oxide nano microspheres, the middle layer is the light absorbent, and the outer shell is polyurethane. The blue light prevention coating expands the spectrum blocking range from an ultraviolet spectrum region to a blue light spectrum region, and has the performance of distinguishing and absorbing blue light of different wave bands under the condition of keeping high transmittance. The blue light prevention coating is matched with a photochromic coating material and is integrated with functions, the transmittance can be automatically adjusted according to the intensity of light, and light and shade can be controlled by selectively transmitting beneficial light and cutting off harmful light, so that light can be transmitted as required.

Description

Blue light/color change prevention dual-function coating optical material and preparation method thereof

Technical Field

The invention belongs to the technical field of light absorption materials, and particularly relates to an optical material with specific absorption on different wavelengths in a 280-450nm spectral region and a preparation method thereof.

Background

It is known that ultraviolet light can harm the eyes of people, and in addition, blue light in visible light can also cause damage to the eyes. The blue light is used as part of visible light, has extremely high energy, the wavelength range is 400-500 nm, and with the wide popularization of electronic products such as computers, mobile phones and ipads, the unnatural light taking the blue light as a main body can cause irreversible damage to human eyes, and the problems of human eyes dryness, fatigue, lacrimation, myopia acceleration, yellow spot region diseases and the like are caused. Issuing an orange early warning according to the World Health Organization (WHO) 2009: the potential stealth threat of blue light to humans will far exceed the devastating effects of sudan red, melamine, SARS, etc., with at least 30000 people becoming blind each year from the radiation of blue light. Most of the existing photochromic optical materials are prepared by adding a photochromic material into optical resin, and the preparation process is a 'basic prevention' process, and the materials can block the damage of ultraviolet light and strong light when being irradiated by sunlight (in a bright environment), but can not block blue light when being irradiated by dark environment (in a room), namely, the photochromic optical materials are discolored and cannot prevent the blue light; human eyes are insensitive to the visual objects and color discrimination of blue light in the range of 400-440nm, the wavelength of the light wave in the wave band is short, the energy is high, the damage to the eyes is large, the light is harmful blue light, and the optical material (device) keeps low transmittance for the part of the blue light; the 440-wavelength 500nm range is medium-long wave blue light, so that the injury to human eyes is relatively small, the pupil constriction can be helped, the color of an object is displayed, the blue light is beneficial, and a certain transmittance is kept for the part of blue light under the condition of ensuring the reality of an object viewing picture. Foreign blue light protection materials mostly adopt a film coating technology, and the preparation process is a 'film prevention' process, namely blue light is absorbed by a blue light protection film, the total blue light effective rate can only reach about 17%, and the protection of short, medium and long blue spectral regions cannot be distinguished; in addition, the strong light is difficult to block in the bright environment (sunlight), and the human eyes are greatly damaged by light irradiation, namely, the blue light is prevented from changing color.

In terms of preparation process, the existing photochromic 'base prevention' process cannot be matched and compatible with the blue light prevention 'film prevention' process, because the surface blue light film absorbs a large amount of ultraviolet rays, the ultraviolet rays entering the optical material matrix are reduced, and the photochromic efficiency is obviously reduced due to the lack of excitation of the ultraviolet rays. The future development trend of the optical material technology is to develop a multifunctional fusion technology, and the single function can not meet the integration and intelligentization requirements of people on optical materials and devices in the future. Therefore, the absorption of the spectral line needs to be regulated, the technology and the process of the high-performance intelligent optical material are developed, the transmittance can be automatically regulated according to the intensity of light, and the light and shade can be controlled and the light can be transmitted as required by selectively transmitting beneficial light and cutting off harmful light, so that the method has great significance.

Disclosure of Invention

The invention aims to provide a blue light/color change prevention dual-function coating optical material and a preparation method thereof. Wherein the blue-light-proof coating is doped with polyurethane/light absorbent/titanium oxide nano composite microspheres. The inner core of the nano composite microsphere is titanium oxide nano particles of which the surfaces are modified with light absorbers, and the shell is coated with polyurethane to form a composite core-shell structure. The material has the performance of distinguishing and absorbing blue light of different wave bands under the condition of keeping high transmittance by expanding the spectrum range from an ultraviolet spectrum region to a blue light spectrum region, wherein the transmittance of the 280 plus 380nm ultraviolet is less than 1 percent, the transmittance of the 400 plus 440nm short-wave blue light is less than 5 percent, and the transmittance of the 460 plus 500nm spectrum region blue light is more than 50 percent; the blue light prevention material can be matched with a photochromic coating material and is integrated with functions, the transmittance can be automatically adjusted according to the intensity of light, and light and shade can be controlled by selectively transmitting beneficial light and stopping harmful light, so that light can be transmitted as required. The LED lamp can be widely applied to the fields of automobile windows, optical protective glass, LED lamp protective films, mobile phone protective screens, ophthalmologic protective equipment and the like, and the harm of harmful light to human eyes is solved.

In order to achieve the purpose, the invention provides the following technical scheme:

a blue light prevention/color change double-function coating optical material comprises an optical substrate, a blue light prevention coating and a photochromic coating; the photochromic coating is positioned on the optical substrate and contacts with the optical surface firstly, and the blue-light-proof coating is positioned on the optical substrate and contacts with the optical surface later; or the blue-light-proof coating is positioned between the photochromic coating and the surface of the optical substrate which is firstly contacted with light;

the blue-light-proof coating is prepared by dispersing polyurethane/light absorber/titanium oxide nano composite microspheres in polythiourethane; the weight ratio of the polyurethane/light absorbent/titanium oxide nano composite microspheres to the polythiourethane is 1: 20-200;

the inner core of the polyurethane/light absorbent/titanium oxide nano composite microsphere is titanium oxide mesoporous nano microsphere, the middle layer is the light absorbent, and the shell is polyurethane; the outer diameter of the composite microsphere is 8-32nm, wherein the diameter of the titanium oxide mesoporous nano microsphere is 3-15 nm, the thickness of the middle layer is 0.5-2.5 nm, and the thickness of the shell is 2-6 nm; the weight ratio of the titanium oxide to the light absorbent to the polyurethane is 1: 0.2-0.6: 0.2-1;

the titanium oxide mesoporous nano-microsphere is composed of monodisperse titanium oxide nanocrystals or crystal grains, and the light absorbent particles in the middle layer are dispersed on the surface or in the pores of the titanium oxide mesoporous nano-microsphere.

Preferably, the polyurethane is formed by polymerizing an isocyanate monomer compound containing two or more isocyanate groups and an alcohol compound;

the blue light/discoloration resistant dual function coated optical material as described above, preferably, the isocyanate monomer compound is selected from the group consisting of: at least one of toluene diisocyanate, diphenylmethane-4, 4' -diisocyanate, 1, 6-hexamethylene diisocyanate, m-xylylene diisocyanate, naphthalene-1, 5-diisocyanate, methylcyclohexyl diisocyanate, dicyclohexylmethane diisocyanate, tetramethylxylylene diisocyanate, and isophorone diisocyanate;

preferably, the alcohol compound is at least one of n-butanol, polytetrahydrofuran ether glycol, pentaerythritol, ethylene glycol, propylene glycol, butanediol, hexanediol, neopentyl glycol and trimethylolpropane.

The blue light/discoloration preventing dual-function coated optical material as described above, preferably, the light absorber is an ultraviolet absorber selected from at least one of UV-P, UV-326, UV-327, UV-328, UV-329, UV-360, UV-531, UV-928 and quinophthalone light absorbers.

The blue light prevention/discoloration prevention dual-functional coating optical material is preferably prepared by the following method:

a. preparing a photosensitization titanium oxide nano material:

adding sodium acetate into pure water, heating to 65-100 ℃, adding titanium oxide mesoporous nano microspheres after the sodium acetate is completely dissolved, stirring for 10-20 minutes, cooling to room temperature, filtering, separating and precipitating, washing, then adding ethanol, stirring, adding a light absorbent, stirring for 20-30 minutes, standing for 40-100 minutes, filtering, collecting precipitate, and drying to obtain a titanium oxide nano material coated with the light absorbent; wherein the mass ratio of the sodium acetate to the titanium oxide is (0.1-0.9) to 1; the mass ratio of the light absorbent to the titanium oxide is (0.2-0.9) to (0.5-3.0); the mass ratio of the sodium acetate, the pure water and the ethanol is (5-10) to 100 to (100-180);

b. preparing polyurethane/light absorbent/titanium oxide blue-light-proof nano composite microspheres:

b, adding the titanium oxide nano material coated with the light absorbent prepared in the step a and an isocyanate monomer compound into a butyl acetate solvent, uniformly stirring, and then sequentially adding an alcohol compound and tween 80; wherein the mass ratio of the titanium oxide nano material coated by the light absorbent, the isocyanate monomer compound, the alcohol compound, the Tween 80 and the butyl acetate solvent is as follows: (0.5-1.2): (0.4-0.9): (0.4-0.5): (1.0-2.0): (300-); keeping the temperature at 15-25 ℃, and carrying out prepolymerization reaction for 40-60min under stirring to obtain a prepolymer solution; adding a chain extender and a catalyst into a prepolymer solution, heating the chain extender, the catalyst and an isocyanate monomer compound to the mass ratio of (5-10) to (0.2-0.5) to (9-15) to perform polymerization chain extension reaction for 10-20min at the temperature of 45-90 ℃ under stirring, generating polyurethane coating sediment, filtering, washing and drying the sediment to obtain the polyurethane/light absorber/titanium oxide three-layer composite core-shell structure blue-light-proof nano composite microsphere.

The blue light/color change prevention dual-function coating optical material is preferably a mixture of n-butyl alcohol and polytetrahydrofuran ether glycol, wherein the mass ratio of the n-butyl alcohol to the polytetrahydrofuran ether glycol is (1-3): (9-11);

the blue light/color change prevention dual-function coating optical material is preferably prepared by adding a chain extender into a solvent;

the blue light/discoloration preventing dual-function coating optical material is characterized in that the catalyst is dibutyltin dilaurate;

the blue light/color change preventing dual-function coating optical material is preferably sodium acetate anhydrous and sodium acetate trihydrate, and preferably sodium acetate trihydrate.

The blue light prevention/color change dual-function coating optical material comprises the following components in part by weight:

A. preparation of blue light prevention coating liquid

The blue light prevention coating liquid comprises the following three components:

(1) a component A:

60-75 parts by weight of polythiourethane monomer

2-9 parts by weight of polyurethane/light absorbent/titanium oxide nano composite microspheres

(2) B, component B:

10-26 parts by weight of an isocyanate-based curing agent

(3) C, component C:

8-30 parts by weight of diluent

Adding the polythiourethane monomer and the polyurethane/spiropyran/zinc sulfide photochromic composite microspheres into a container according to the proportion, uniformly stirring for 15-30 minutes at room temperature to obtain a component A, and uniformly mixing the component A, the component B and the component C according to the proportion;

B. the viscosity is adjusted by a thinner, and then the coating layer is formed by coating on the surface of the optical substrate, and the coating layer is cured by room temperature, light irradiation, or heating, to prepare the blue light prevention coating layer.

The blue light prevention/color change dual-function coating optical material comprises the following components in part by weight:

I. preparing coating liquid of three components A, B and C;

II, during coating, uniformly mixing the component A, the component B and the component C in proportion, and adding a diluent to adjust the viscosity to be 20-350 cp at normal temperature to obtain a blue-light-proof coating liquid;

optical substrate pretreatment: subjecting an optical substrate to one or more of the following pre-treatments: chemical treatment with alkaline aqueous solution or acidic aqueous solution, grinding treatment, plasma treatment with different air pressures, corona discharge treatment, UV ozone treatment and hardening treatment;

IV, coating: coating, spraying or dip-coating the optical substrate after pretreatment by using the blue-light-proof coating liquid prepared in the step II to form a blue-light-proof coating on the substrate, so as to obtain a blue-light-proof optical material;

more preferably, step IV employs a dip coating method, which is specifically performed as follows: immersing the pretreated optical base material into the blue-light-proof coating liquid, immersing for 3-5 minutes at room temperature, slowly lifting the optical base material out of the coating liquid, moving to an oven, setting the temperature at 35-65 ℃, and baking for 45-90 minutes to form a first blue-light-proof coating; and then immersing the optical base material into the blue-light-proof coating liquid again, immersing for 3-5 minutes at room temperature, slowly lifting the optical base material out of the coating liquid, moving the optical base material into an oven, setting the temperature at 35-65 ℃, and baking for 45-90 minutes to form a second blue-light-proof coating, so as to obtain the blue-light-proof optical material.

The blue light/color change prevention dual-function coating optical material is preferably characterized in that the polythiourethane monomer is at least one of 2,2 '-dimercaptoethyl sulfide, 2' -dimercaptoethyl thioethane, 2, 3-dimercaptoethyl thiopropyl mercaptan or 1,2, 3-trimercaptoethyl thiopropane;

preferably, the isocyanate-type curing agent is at least one of a toluene diisocyanate curing agent, a diphenylmethane-4, 4' -diisocyanate curing agent, a 1, 6-hexamethylene diisocyanate curing agent, an m-xylylene diisocyanate curing agent, a methylcyclohexyl diisocyanate curing agent and an isophorone diisocyanate curing agent;

the above-mentioned blue light/discoloration preventing dual-functional coated optical material preferably has at least one of dichloromethane, butyl acetate, methyl acetate, ethanol, butanol, acetone, toluene, xylene, diethyl ether and polytetrahydrofuran ether glycol as the diluent.

Preferably, the optical substrate is optical glass, optical plastic or optical crystal, and the thickness of the blue light prevention coating is 10-100 μm.

In another aspect, the present invention provides a method for preparing the above-mentioned blue light/discoloration-preventing dual-functional coating optical material, wherein the method can select one of the following two schemes:

the first scheme is as follows: coating the blue-light-proof coating liquid, and coating a photochromic coating after completely curing;

scheme II: the front surface of the marked optical substrate is a light contact surface firstly, the back surface of the marked optical substrate is a back light contact surface, the front surface is coated with a photochromic coating, and the back surface is coated with a blue-light-proof coating.

The photochromic coating of the present invention can be prepared using commercially available photochromic coating solutions or according to published methods, such as: chinese patent application No. 201711110838.6 discloses a preparation method of a spiropyran photochromic coating.

The titanium oxide mesoporous nano-microsphere can be purchased in the market, such as titanium oxide nano-particles produced by Jiangsu Huatiantong scientific and technological limited company, and can also be prepared according to the following method, but not limited to the following method:

10mL of titanium tetrachloride was added dropwise to 95mL of acetonitrile, and 85mL of deionized water was slowly added to the round-bottom flask after the reaction was complete to form a pale yellow powder (titanium tetrachloride-acetonitrile complex intermediate). Then heating and refluxing for 6-18h, placing the product in a centrifuge tube at the rotating speed of 4000r/min for centrifuging for 30min, then pouring out the supernatant, drying at 45 ℃, and grinding to obtain the mesoporous structure TiO₂And (3) nano powder.

The invention has the beneficial effects that: the blue-light-proof nano composite microspheres are doped in the blue-light-proof coating of the optical material, are of a polyurethane/light absorber/titanium oxide three-layer composite core-shell structure, and are modified with the light absorber on the surface of porous nano titanium oxide, so that the Van der Waals area of light-absorbing molecules is increased, a conjugated system is increased, the mutual synergistic action among different molecules is enhanced, the photocatalytic activity is enhanced, the spectral response is more sensitive, the spectral response range is expanded from an ultraviolet area to a visible light area, and the absorption wavelength is red-shifted from 410nm to 450 nm. The blue light-proof nano composite microspheres are doped into the blue light-proof coating to prepare the blue light-proof material, and are not limited by organic pollution, high temperature and other environments in the production process of an optical matrix. The blue light prevention material can be combined with a photochromic material to realize multifunctional integration, can automatically adjust the transmittance according to the intensity of light, has the functions of preventing strong light and ultraviolet rays under the condition of strong light, has the functions of preventing ultraviolet rays and blue light in a dark place, has controllable light and shade, transmits light as required, and achieves the effects of preventing blue light and changing color.

Drawings

FIG. 1 is an absorption spectrum of a blue light-blocking coating solution prepared in example 1.

FIG. 2 is an absorption spectrum of blue-light preventing optical glass prepared in example 1.

FIG. 3 is an absorption spectrum chart of the blue light/discoloration preventing bifunctional optical glass prepared in example 1.

FIG. 4 is an absorption spectrum diagram of the blue light/discoloration preventing bifunctional optical resin prepared in example 1.

FIG. 5 is a TEM image of the titania-modified nanomaterial prepared in example 1.

FIG. 6 is a high resolution TEM HTEM image of the polyurethane/light absorber/titanium oxide nanocomposite microspheres prepared in example 1.

Detailed Description

The invention is further illustrated by the following specific examples, which are not intended to limit the scope of the invention.

Some of the raw material sources used in the examples below:

the nano titanium oxide is a titanium oxide mesoporous nano microsphere which is purchased from Jiangsu Huatiantong science and technology limited company, and has the product types: h-yt-30.

The photochromic coating liquid contains a spiropyran photochromic compound, and a manufacturer: jiangsu Visco New Material Co., Ltd, product type: SK-02.

Example 1: preparing blue light-proof nano composite microspheres, blue light-proof coating liquid, blue light-proof optical glass, blue light-proof/color-changing dual-functional optical glass and blue light-proof/color-changing dual-functional optical resin material

Preparing blue light prevention nano composite microspheres:

1. adding 80g of sodium acetate into 1000g of pure water, gradually heating to 100 ℃, changing into a transparent sodium acetate aqueous solution, adding 130g of nano titanium oxide, stirring for 20 minutes, cooling to room temperature, gradually layering and precipitating reaction liquid, filtering, separating and washing solid and liquid, adding 1500g of ethanol, stirring again, adding 50g of ultraviolet absorbent UV-P, stirring for 20 minutes, standing for 50 minutes, filtering, collecting precipitate, and drying to obtain a titanium oxide modified nano material;

FIG. 5 is a TEM image of the titania-modified nanomaterial. It can be seen that the appearance is spherical, the particle size is about 10nm, the size is uniform, and the observed lattice fringes are electron diffraction rings of the sample, which indicates that the sample is good in crystallinity. In addition, the change in brightness of the titanium oxide particles is clearly observed in the figure, which is caused by the mesopores on the surface of the titanium oxide particles.

2. Adding 7g of titanium oxide modified nano material and 6.5g of 1, 6-hexamethylene diisocyanate into 4000g of butyl acetate solvent, uniformly stirring, and adding 1.0g of n-butyl alcohol, 3.5g of polytetrahydrofuran ether glycol and 12g of tween 80; keeping the temperature at 20 ℃, carrying out prepolymerization reaction for 50min under stirring, adding 4.2g of ethylene glycol and 0.1g of dibutyltin dilaurate, heating to 60 ℃, stirring for 20min, collecting, filtering, washing and drying precipitates to obtain the blue-light-proof nano composite microspheres.

FIG. 6 is a high resolution transmission electron microscope HTEM image of blue light prevention nano composite microspheres. It can be seen that the appearance is spherical, the particle size is about 15nm, and the outer shell of the polyurethane is colorless and transparent, so the polyurethane is displayed as a white bright ring in the transmission electron microscope picture. The average thickness of the ultraviolet absorbent and the polyurethane coating shell is about 2.5nm by calculation of a Sherrer formula (D ═ K/beta cos theta) and Zeta potential analysis.

Preparing blue light prevention coating liquid:

1. preparing a component A: adding 50g of polyurethane/light absorbent/titanium oxide nano composite microspheres into 650g of 2, 3-dimercaptoethyl thiopropyl mercaptan (BES) monomer, and uniformly stirring at room temperature for 25min to obtain a component A;

2. preparing blue-light-proof coating liquid: 180g of m-xylylene diisocyanate curing agent (component B), 200g of dichloromethane (component C) and 700g of component A are uniformly mixed to obtain the blue light prevention coating liquid.

(III) preparing blue light prevention optical glass:

and (3) marking A and B on two surfaces of the cleaned 2mm optical glass substrate, wherein the surface A is a first contact light surface, the surface B is a second contact light surface, spraying the blue light prevention coating liquid on the surface B of the optical glass substrate, after the spraying is finished, moving the optical glass substrate to an oven, setting the temperature at 50 ℃, baking for 100 minutes, slowly cooling to room temperature, standing for 24 hours, repeatedly spraying for the second time, and completely curing to obtain the blue light prevention optical material, wherein the thickness of the blue light prevention coating is 42 microns.

Preparing the blue light prevention/color change dual-function optical glass:

carrying out photochromic coating liquid spraying on the surface A of the blue-light-proof optical material, moving the optical material into a baking oven after the spraying is finished, setting the temperature at 45 ℃, and baking for 80 minutes; after curing, spraying the photochromic coating liquid once again, and obtaining the optical glass with double functions of blue light prevention and discoloration after complete curing. The thickness of the photochromic coating was 43 μm.

Preparing the blue light prevention/color change difunctional optical resin material:

adding 2.3g of the blue-light-proof nano composite microspheres prepared in the step (one) into 100ml of m-Xylylene Diisocyanate (XDI), uniformly stirring for 20 minutes, adding 85ml of 2, 3-dimercaptoethyl thiopropanethiol, and mixing and stirring; adding 3.6g of dibutyltin Dilaurate (DBTL) catalyst, then carrying out prepolymerization on the mixture at 65 ℃ for 45 minutes, filtering, carrying out vacuum defoamation, pouring the raw materials into a mold, heating the raw materials to 120 ℃ according to a curing program, curing for 18 hours, cooling to room temperature, demolding, and cleaning to obtain the polyurethane optical sheet doped with the blue-light-resistant nano composite microspheres.

Spraying photochromic coating liquid on the polyurethane optical sheet which is firstly contacted with the optical surface, moving the optical sheet into a baking oven after the spraying is finished, setting the temperature at 45 ℃, and baking for 80 minutes; and after curing, repeatedly spraying the photochromic coating liquid once, and completely curing to obtain the optical resin material with the dual functions of blue light prevention and discoloration. The thickness of the photochromic coating was 40 μm.

Comparative example 1: preparing the blue light prevention/color change dual-functional optical resin material (without blue light prevention nano composite microspheres) doped with UV-titanium oxide

Adding 2.3g of nano titanium oxide into 100ml of m-Xylylene Diisocyanate (XDI), uniformly stirring for 20 minutes, adding 85ml of 2, 3-dimercaptoethyl thiopropanethiol, adding 1.85g of ultraviolet absorbent UV-P, mixing and stirring; adding 3.6g of dibutyltin Dilaurate (DBTL) catalyst, then carrying out prepolymerization on the mixture at 65 ℃ for 45 minutes, filtering, carrying out vacuum defoaming, pouring the raw materials into a mold, heating the raw materials to 120 ℃ according to a curing procedure, curing for 18 hours, cooling to room temperature, demolding, and cleaning to obtain the UV-titanium oxide doped polyurethane optical sheet. Spraying photochromic coating liquid on the polyurethane optical sheet which is firstly contacted with the optical surface, moving the optical sheet into a baking oven after the spraying is finished, setting the temperature at 45 ℃, and baking for 80 minutes; and after curing, repeatedly spraying the photochromic coating liquid once, and completely curing to obtain the optical resin material with the dual functions of blue light prevention and discoloration. The thickness of the photochromic coating was 43 μm.

Comparative example 2: preparation of an optical resin Material (not containing titanium oxide) containing an ultraviolet absorber

Adding 100ml of m-Xylylene Diisocyanate (XDI) into 85ml of 2, 3-dimercaptoethyl thiopropanethiol, adding 1.85g of ultraviolet absorbent UV-P, mixing and stirring; adding 3.6g of dibutyltin Dilaurate (DBTL) catalyst, then carrying out prepolymerization on the mixture at 65 ℃ for 45 minutes, filtering, carrying out vacuum defoaming, pouring the raw materials into a mold, heating the raw materials to 120 ℃ according to a curing procedure, curing for 18 hours, cooling to room temperature, demolding, and cleaning to obtain a polyurethane optical sheet containing an ultraviolet absorber; spraying photochromic coating liquid on the polyurethane optical sheet which is firstly contacted with the optical surface, moving the optical sheet into a baking oven after the spraying is finished, setting the temperature at 45 ℃, and baking for 80 minutes; and after curing, spraying the photochromic coating liquid once again, and completely curing to obtain the optical resin material containing the ultraviolet absorbent. The thickness of the photochromic coating was 43 μm.

Comparative example 3: preparation of optical resin Material containing Nano titanium oxide particles (containing no ultraviolet absorber)

Adding 2.3g of nano titanium oxide into 100ml of m-Xylylene Diisocyanate (XDI), uniformly stirring for 20 minutes, adding 85ml of 2, 3-dimercaptoethyl thiopropanethiol, and mixing and stirring; adding 3.6g of dibutyltin Dilaurate (DBTL) catalyst, then carrying out prepolymerization on the mixture at 65 ℃ for 45 minutes, filtering, carrying out vacuum defoaming, pouring the raw materials into a mold, heating the raw materials to 120 ℃ according to a curing procedure, curing for 18 hours, cooling to room temperature, demolding, and cleaning to obtain a titanium oxide-doped polyurethane optical sheet; spraying photochromic coating liquid on the polyurethane optical sheet which is firstly contacted with the optical surface, moving the optical sheet into a baking oven after the spraying is finished, setting the temperature at 45 ℃, and baking for 80 minutes; and after curing, spraying the photochromic coating liquid for one time repeatedly, and obtaining the optical resin material containing the titanium oxide nano particles after complete curing. The thickness of the photochromic coating was 40 μm.

Example 2: preparing blue light-proof nano composite microspheres, blue light-proof coating liquid, blue light-proof optical glass, blue light-proof/color-changing dual-functional optical glass and blue light-proof/color-changing dual-functional optical resin material

Preparing blue light prevention nano composite microspheres:

adding 95g of sodium acetate into 1000g of pure water, gradually heating to 100 ℃, changing into a transparent sodium acetate aqueous solution, adding 180g of nano titanium oxide, stirring for 20 minutes, cooling to room temperature, gradually layering and precipitating reaction liquid, filtering, separating and washing solid and liquid, adding 1700g of ethanol, stirring, adding 36g of ultraviolet absorbent UV-P, stirring for 25 minutes, standing for 50 minutes, filtering, collecting precipitate, and drying to obtain a titanium oxide modified nano material;

adding 7g of titanium oxide modified nano material and 4.2g of isophorone diisocyanate into 3500g of butyl acetate solvent, stirring uniformly, and adding 1.0g of n-butyl alcohol, 3.5g of polytetrahydrofuran ether glycol and 12g of tween 80; keeping the temperature at 25 ℃, carrying out prepolymerization reaction for 50min under stirring, adding 2.7g of ethylene glycol and 0.1g of dibutyltin dilaurate, heating to 60 ℃, stirring for 20min, collecting, filtering, washing and drying precipitates to obtain the blue-light-proof nano composite microspheres.

Preparing blue light prevention coating liquid:

1. preparing a component A: adding 50g of polyurethane/light absorbent/titanium oxide nano composite microspheres into 350g of 2, 3-dimercaptoethyl thiopropyl mercaptan (BES) monomer, and uniformly stirring at room temperature for 25min to obtain a component A;

2. preparing blue-light-proof coating liquid: 120g of m-xylylene diisocyanate curing agent (component B), 100g of dichloromethane (component C) and 400g of component A were uniformly mixed to obtain a blue light-proof coating liquid.

(III) preparing blue light prevention optical glass:

and (3) marking A and B on two surfaces of the cleaned 2mm optical glass substrate, wherein the surface A is a first contact light surface, the surface B is a second contact light surface, spraying the blue light prevention coating liquid on the surface B of the optical glass substrate, after the spraying is finished, moving the optical glass substrate to an oven, setting the temperature at 50 ℃, baking for 100 minutes, slowly cooling to room temperature, standing for 24 hours, repeatedly spraying for the second time, and completely curing to obtain the blue light prevention optical material, wherein the thickness of the blue light prevention coating is 40 mu m.

Preparing the blue light prevention/color change dual-function optical glass:

carrying out photochromic coating liquid spraying on the surface A of the blue-light-proof optical material prepared in the step (three), moving the optical material to a baking oven after the spraying is finished, setting the temperature at 45 ℃, and baking for 80 minutes; and after curing, spraying the photochromic coating liquid for one time repeatedly, and obtaining the optical material with double functions of blue light prevention and color change after complete curing. The thickness of the photochromic coating was 45 μm.

Preparing the blue light prevention/color change difunctional optical resin material:

marking A and B on two surfaces of a 2mm polyurethane optical substrate after cleaning, wherein the surface A is a light contact surface firstly, the surface B is a rear light contact surface, spraying photochromic coating liquid on the surface A of the optical substrate respectively, spraying the blue light prevention coating liquid on the surface B, after spraying, moving the optical substrate into a baking oven, setting the temperature at 50 ℃, baking for 100 minutes, slowly cooling to room temperature, standing for 24 hours, repeatedly spraying for the second time, and completely curing to obtain the blue light prevention/color change dual-functional optical resin material. The thickness of the blue-blocking coating was 45 μm and the thickness of the photochromic coating was 42 μm.

Example 3: preparing blue light-proof nano composite microspheres, blue light-proof coating liquid, blue light-proof optical glass, blue light-proof/color-changing dual-functional optical glass and blue light-proof/color-changing dual-functional optical resin material

Preparing blue light prevention nano composite microspheres:

adding 75g of sodium acetate into 1000g of pure water, gradually heating to 100 ℃, changing into a transparent sodium acetate aqueous solution, adding 100g of nano titanium oxide, stirring for 20 minutes, cooling to room temperature, gradually layering and precipitating reaction liquid, filtering, separating and washing solid and liquid, adding 1300g of ethanol, stirring, adding 28g of ultraviolet absorbent UV-P, stirring for 20 minutes, standing for 50 minutes, filtering, collecting precipitate, and drying to obtain a titanium oxide modified nano material;

adding 7g of titanium oxide modified nano material and 7g of m-xylylene diisocyanate into 4000g of butyl acetate solvent, uniformly stirring, and adding 1.0g of n-butyl alcohol, 3.5g of polytetrahydrofuran ether glycol and 15g of tween 80; keeping the temperature at 20 ℃, carrying out prepolymerization reaction for 50min under stirring, adding 4.2g of ethylene glycol and 0.15g of dibutyltin dilaurate, heating to 55 ℃, stirring for 20min, collecting, filtering, washing and drying precipitates to obtain the blue-light-proof nano composite microspheres.

Preparing blue light prevention coating liquid:

1. preparing a component A: adding 50g of polyurethane/light absorbent/titanium oxide nano composite microspheres into 850g of 2, 3-dimercaptoethyl thiopropyl mercaptan (BES) monomer, and uniformly stirring at room temperature for 25min to obtain a component A;

2. preparing blue-light-proof coating liquid: 250g of m-xylylene diisocyanate curing agent (component B), 230g of dichloromethane (component C) and 900g of component A are uniformly mixed to obtain the blue light prevention coating liquid.

(III) preparing blue light prevention optical glass:

and (3) spraying the blue-light-proof coating liquid on two sides of the cleaned 2mm optical glass substrate, after the spraying is finished, moving the optical glass substrate into an oven, setting the temperature at 50 ℃, baking the optical glass substrate for 100 minutes, slowly cooling the optical glass substrate to room temperature, and standing the optical glass substrate for 24 hours to obtain the blue-light-proof optical material. The thickness of the single-sided blue-light-proof coating is 42 μm.

Preparing the blue light prevention/color change dual-function optical glass:

spraying the blue-light-proof coating liquid on the surface of the cleaned 2mm optical glass substrate which is firstly contacted with the light ray, after the spraying is finished, moving the optical glass substrate into a baking oven, setting the temperature at 50 ℃, baking the optical glass substrate for 100 minutes, slowly cooling the optical glass substrate to room temperature, and standing the optical glass substrate for 24 hours to obtain a first blue-light-proof coating; then spraying a second photochromic coating on the first blue-light-proof coating, moving the second photochromic coating into a baking oven after the spraying is finished, setting the temperature at 45 ℃, and baking for 80 minutes; and repeatedly spraying the photochromic coating liquid once, and completely curing to obtain the optical glass with the dual functions of blue light prevention and color change. The thickness of the blue-blocking coating was 42 μm and the thickness of the photochromic coating was 42 μm.

Preparing the blue light prevention/color change difunctional optical resin material:

marking A and B on two surfaces of a 2mm polyurethane optical substrate after cleaning, wherein the surface A is a light contact surface firstly, the surface B is a rear light contact surface, spraying photochromic coating liquid on the surface A of the optical substrate respectively, spraying the blue light prevention coating liquid on the surface B, after spraying, moving the optical substrate into a baking oven, setting the temperature at 50 ℃, baking for 90 minutes, slowly cooling to room temperature, standing for 20 hours, repeatedly spraying for the second time, and completely curing to obtain the blue light prevention/color change dual-functional optical resin material. The thickness of the blue-blocking coating was 44 μm and the thickness of the photochromic coating was 40 μm.

Example 4: preparing blue light-proof nano composite microspheres, blue light-proof coating liquid, blue light-proof optical glass, blue light-proof/color-changing dual-functional optical glass and blue light-proof/color-changing dual-functional optical resin material

Preparing blue light prevention nano composite microspheres:

adding 85g of sodium acetate into 1000g of pure water, gradually heating to 100 ℃, changing into a transparent sodium acetate aqueous solution, adding 155g of nano titanium oxide, stirring for 20 minutes, cooling to room temperature, gradually layering and precipitating reaction liquid, filtering, separating and washing solid and liquid, adding 1600g of ethanol, stirring, adding 45g of ultraviolet absorbent UV-P, stirring for 20 minutes, standing for 50 minutes, filtering, collecting precipitate, and drying to obtain a titanium oxide modified nano material;

adding 7g of titanium oxide modified nano material and 5g of isophorone diisocyanate into 3600g of butyl acetate solvent, uniformly stirring, and adding 1.0g of n-butyl alcohol, 3g of polytetrahydrofuran ether glycol and 12g of tween 80; keeping the temperature at 18 ℃, carrying out prepolymerization reaction for 50min under stirring, adding 3g of ethylene glycol and 0.1g of dibutyltin dilaurate, heating to 60 ℃, stirring for 20min, collecting, filtering, washing and drying precipitates to obtain the blue-light-proof nano composite microspheres.

Preparing blue light prevention coating liquid:

1. preparing a component A: adding 50g of polyurethane/light absorbent/titanium oxide nano composite microspheres into 450g of 2, 3-dimercaptoethyl thiopropyl mercaptan (BES) monomer, and uniformly stirring at room temperature for 25min to obtain a component A;

2. preparing blue-light-proof coating liquid: 150g of m-xylylene diisocyanate curing agent (component B), 160g of dichloromethane (component C) and 500g of component A are uniformly mixed to obtain the blue light prevention coating liquid.

(III) preparing blue light prevention optical glass:

and (3) spraying the blue-light-proof coating liquid on two sides of the cleaned 2mm optical glass substrate, after the spraying is finished, moving the optical glass substrate into an oven, setting the temperature at 50 ℃, baking the optical glass substrate for 100 minutes, slowly cooling the optical glass substrate to room temperature, and standing the optical glass substrate for 24 hours to obtain the blue-light-proof optical material. The thickness of the single-sided blue-light-proof coating is 42 μm.

Preparing the blue light prevention/color change dual-function optical glass:

spraying the blue-light-proof coating liquid on the surface of the cleaned 2mm optical glass substrate which is firstly contacted with the light ray, after the spraying is finished, moving the optical glass substrate into a baking oven, setting the temperature at 50 ℃, baking the optical glass substrate for 100 minutes, slowly cooling the optical glass substrate to room temperature, and standing the optical glass substrate for 24 hours to obtain a first blue-light-proof coating; then spraying a second photochromic coating on the first blue-light-proof coating, moving the second photochromic coating into a baking oven after the spraying is finished, setting the temperature at 45 ℃, and baking for 80 minutes; and repeatedly spraying the photochromic coating liquid once, and completely curing to obtain the optical glass with the dual functions of blue light prevention and color change. The thickness of the blue-blocking coating was 43 μm and the thickness of the photochromic coating was 45 μm.

Preparing the blue light prevention/color change difunctional optical resin material:

adding 2.5g of the blue-light-proof nano composite microspheres prepared in the step (one) into 100ml of m-Xylylene Diisocyanate (XDI), uniformly stirring for 20 minutes, adding 70ml of 2, 3-dimercaptoethyl thiopropanethiol, and mixing and stirring; adding 3.2g of dibutyltin Dilaurate (DBTL) catalyst, then carrying out prepolymerization on the mixture at 65 ℃ for 45 minutes, filtering, carrying out vacuum defoaming, pouring the raw materials into a mold, heating the raw materials to 120 ℃ according to a curing program, curing for 20 hours, cooling to room temperature, demolding, cleaning to obtain a polyurethane optical sheet doped with blue-light-proof nano composite microspheres, spraying photochromic coating liquid on the polyurethane optical sheet firstly contacting with a light surface, moving to an oven after spraying, setting the temperature at 45 ℃, and baking for 80 minutes; and after curing, repeatedly spraying the photochromic coating liquid once, and completely curing to obtain the optical resin material with the dual functions of blue light prevention and discoloration. The thickness of the photochromic coating was 43 μm.

Example 5: preparing blue light-proof nano composite microspheres, blue light-proof coating liquid, blue light-proof optical glass, blue light-proof/color-changing dual-functional optical glass and blue light-proof/color-changing dual-functional optical resin material

Preparing blue light prevention nano composite microspheres:

adding 65g of sodium acetate into 1000g of pure water, gradually heating to 100 ℃, changing into a transparent sodium acetate aqueous solution, adding 100g of nano titanium oxide, stirring for 20 minutes, cooling to room temperature, gradually layering and precipitating reaction liquid, filtering, separating and washing solid and liquid, adding 1200g of ethanol, stirring, adding 15g of ultraviolet absorbent UV-P, stirring for 20 minutes, standing for 50 minutes, filtering, collecting precipitate, and drying to obtain a titanium oxide modified nano material;

adding 7g of titanium oxide modified nano material and 8.4g of 1, 6-hexamethylene diisocyanate into 4500g of butyl acetate solvent, uniformly stirring, and adding 1.0g of n-butyl alcohol, 3.5g of polytetrahydrofuran ether glycol and 18g of tween 80; keeping the temperature at 22 ℃, carrying out prepolymerization reaction for 50min under stirring, adding 5g of ethylene glycol and 0.15g of dibutyltin dilaurate, heating to 55 ℃, stirring for 20min, collecting, filtering, washing and drying precipitates to obtain the blue-light-proof nano composite microspheres.

Preparing blue light prevention coating liquid:

1. preparing a component A: adding 50g of polyurethane/light absorbent/titanium oxide nano composite microspheres into 1150g of 2, 3-dimercaptoethyl thiopropyl mercaptan (BES) monomer, and uniformly stirring at room temperature for 25min to obtain a component A;

2. preparing blue-light-proof coating liquid: 260g of m-xylylene diisocyanate curing agent (component B), 250g of dichloromethane (component C) and 1200g of component A are uniformly mixed to obtain the blue light prevention coating liquid.

(III) preparing blue light prevention optical glass:

and (3) marking A and B on two surfaces of the cleaned 2mm optical glass substrate, wherein the surface A is a first contact light surface, the surface B is a second contact light surface, spraying the blue light prevention coating liquid on the surface B of the optical glass substrate, after the spraying is finished, moving the optical glass substrate to an oven, setting the temperature at 50 ℃, baking for 100 minutes, slowly cooling to room temperature, standing for 24 hours, repeatedly spraying for the second time, and completely curing to obtain the blue light prevention optical material, wherein the thickness of the blue light prevention coating is 42 microns.

Preparing the blue light prevention/color change dual-function optical glass:

carrying out photochromic coating liquid spraying on the surface A of the blue-light-proof optical material, moving the optical material into a baking oven after the spraying is finished, setting the temperature at 45 ℃, and baking for 80 minutes; and after curing, spraying the photochromic coating liquid for one time repeatedly, and obtaining the optical material with double functions of blue light prevention and color change after complete curing. The thickness of the photochromic coating was 43 μm.

Preparing the blue light prevention/color change difunctional optical resin material:

spraying the blue-light-proof coating liquid on the surface of the cleaned 2mm optical resin substrate which is firstly contacted with the light ray, after the spraying is finished, moving the optical resin substrate into a baking oven, setting the temperature at 50 ℃, baking the optical resin substrate for 100 minutes, slowly cooling the optical resin substrate to room temperature, standing the optical resin substrate for 24 hours to obtain a first blue-light-proof coating, and repeatedly spraying the coating once; then spraying photochromic coating liquid on the blue-light-proof coating, moving the coating into a baking oven after the spraying is finished, setting the temperature at 45 ℃, and baking for 80 minutes; and repeatedly spraying the photochromic coating liquid once, and completely curing to obtain the optical resin material with the dual functions of blue light prevention and color change. The thickness of the blue-blocking coating was 42 μm and the thickness of the photochromic coating was 43 μm.

Example 6: optical Property detection experiment

The blue light-proof coating solutions prepared in examples 1 to 5 were respectively subjected to light transmittance (T/%) property detection, wherein the transmittance detection was performed using a UV-8000 type UV-visible spectrophotometer, a shanghai chromatography instrument ltd; the detection method comprises the following steps: directly coating the anti-blue light coating liquid on a prism of an ultraviolet visible light photometer to measure the light transmittance, wherein the detection value of the ultraviolet spectral region is the average value in the range of 280-380nm, and the detection values of the blue light spectral region are respectively selected at 440nm, 460nm and 480 nm; the 680nm position in the visible spectrum is selected as a detection value, and the detection result is listed in the table I. FIG. 1 is an absorption spectrum of a blue light-blocking coating solution prepared in example 1.

Table one blue light prevention coating liquid light transmittance detection condition table unit: t%

Example 7: blue light prevention glass optical property detection

The blue light-proof glass prepared in the embodiments 1 to 5 is respectively subjected to light transmittance (T/%) performance detection, a UV-8000 type ultraviolet visible light photometer of Shanghai Yuan analytical instruments Limited is selected, a visible light region with a wavelength range of 400-780 nm and an ultraviolet region with a wavelength range of 200-400 nm, and different luminophors are adopted as light sources of the instruments. The results are shown in Table II. FIG. 2 is an absorption spectrum of blue-light preventing optical glass prepared in example 1.

Table two blue light-proof optical glass light transmittance detection condition table unit: t%

Example 8: detection of optical performance of blue light prevention/color change dual-functional optical material

The blue light/discoloration-preventing bifunctional optical glass and the bifunctional resin sheet prepared in examples 1 to 5 and comparative examples 1 to 3 were subjected to light transmittance (T/%) property and photochromic response value detection, respectively. A UV-8000 type ultraviolet-visible light double-photometer of Shanghai Yuan analysis instruments ltd is selected, a visible light region with the wavelength range of 400-780 nm and an ultraviolet light region with the wavelength range of 200-400 nm are selected, and different luminophors are adopted as light sources of the instrument. The photochromic response value adopts the ratio of the light transmittance tau v (0) of the tested sample in a fading state to the light transmittance tau v (15) of the tested sample in a discoloring state after 15min illumination, namely: τ v (0)/τ v (15). And (3) irradiating the sample for 30min by using the radiation intensity of the solar simulator, and detecting the visible light transmittance of the sample. The detection method comprises the following steps: adopts a standard light source of a sunlight simulator, the sunlight simulator adopts a 1000W deuterium lamp, and the illumination intensity is (50+5) multiplied by 10³1x, directly installing a sample to be detected between a detector and a light source, after the sample to be detected is centrally positioned, irradiating the sample by using the light source, simultaneously, reducing the radiation intensity of a solar simulator to 30%, and then irradiating the sample, wherein the temperature is set to be 25 ℃, so as to determine the photochromic response value of the sample under medium light illumination. Detection of optical properties of completely faded state: placing the sample in a dark environment for 60 minutes, and then carrying out other optical performance detection, wherein the detection value of the ultraviolet spectral region is the average value of the light transmittance in the 280-380nm spectral range; the detection value of the blue light spectral region is the highest value of the light transmittance in the 380-440nm spectral range; the detection value of the visible spectral region is the lowest value of the light transmittance in the spectral range of 600-780 nm. The results are shown in Table three and Table four. FIG. 3 is an absorption spectrum chart of the blue light/discoloration preventing bifunctional optical glass prepared in example 1. FIG. 4 is an absorption spectrum diagram of the blue light/discoloration preventing bifunctional optical resin prepared in example 1.

Table for testing performance of three samples in color changing state

Table four light transmittance measurements for faded state of samples table units: t%

From the above-mentioned detection results, it can be seen that: the blue light prevention optical material containing the polyurethane/light absorber/titanium oxide nano composite microspheres has the advantages that the red shift amount of an absorption spectrum in an ultraviolet visible region is increased, and the absorption capacity of a harmful spectrum is enhanced, wherein the transmittance of a 280-plus 380nm ultraviolet spectrum region is less than or equal to 0.1%, the transmittance of a 380-plus 440nm blue light spectrum region is less than or equal to 5.5%, the transmittance of a 480nm blue light region is more than or equal to 70%, and the transmittance of a 600-plus 780nm visible light spectrum region is more than or equal to 80%; meanwhile, the blue light prevention optical material can be functionally combined and integrated with a photochromic material, the transmittance can be automatically adjusted according to the intensity of light, the blue light prevention optical material has the function of absorbing different wavelength spectrums in different light and shade environments, the photochromic response value is not less than 1.85, the fading state is 380-440nm, the blue light prevention performance is stronger, and the harm of harmful light to human eyes is better solved.

Claims (13)

1. The blue light prevention/color change double-function coating optical material is characterized by comprising an optical substrate, a blue light prevention coating and a photochromic coating; the photochromic coating is positioned on the optical substrate and contacts with the optical surface firstly, and the blue-light-proof coating is positioned on the optical substrate and contacts with the optical surface later; or the blue-light-proof coating is positioned between the photochromic coating and the surface of the optical substrate which is firstly contacted with light;

the blue-light-proof coating is prepared by dispersing polyurethane/light absorber/titanium oxide nano composite microspheres in polythiourethane; the weight ratio of the polyurethane/light absorbent/titanium oxide nano composite microspheres to the polythiourethane is 1: (20-200);

the inner core of the polyurethane/light absorbent/titanium oxide nano composite microsphere is titanium oxide mesoporous nano microsphere, the middle layer is the light absorbent, and the shell is polyurethane; the outer diameter of the composite microsphere is 8-32nm, wherein the diameter of the titanium oxide mesoporous nano microsphere is 3-15 nm, the thickness of the middle layer is 0.5-2.5 nm, and the thickness of the shell is 2-6 nm; the weight ratio of the titanium oxide to the light absorbent to the polyurethane is 1: (0.2-0.6): (0.2 to 1);

the titanium oxide mesoporous nano-microsphere is composed of monodisperse titanium oxide nanocrystals or crystal grains, and the light absorbent particles in the middle layer are dispersed on the surface or in the pores of the titanium oxide mesoporous nano-sphere;

the light absorber is ultraviolet absorber, and is selected from at least one of UV-P, UV-326, UV-327, UV-328, UV-329, UV-360, UV-531, UV-928 and quinophthalone light absorber.

2. The blue-light/discoloration-preventing dual-functional coated optical material according to claim 1, wherein said polyurethane is prepared by polymerizing an isocyanate monomer compound containing two or more isocyanate groups with an alcohol compound.

3. The blue light/discoloration resistant dual function coated optical material of claim 2, wherein said isocyanate monomer compound is selected from the group consisting of: at least one of toluene diisocyanate, diphenylmethane-4, 4' -diisocyanate, 1, 6-hexamethylene diisocyanate, m-xylylene diisocyanate, naphthalene-1, 5-diisocyanate, methylcyclohexyl diisocyanate, dicyclohexylmethane diisocyanate, tetramethylxylylene diisocyanate, and isophorone diisocyanate;

the alcohol compound is at least one of n-butyl alcohol, polytetrahydrofuran ether glycol, pentaerythritol, ethylene glycol, propylene glycol, butanediol, hexanediol, neopentyl glycol and trimethylolpropane.

4. The blue-light prevention/discoloration dual-functional coating optical material according to claim 1, wherein said polyurethane/light absorber/titanium oxide nanocomposite microsphere is prepared by the following method:

a. preparing a photosensitization titanium oxide nano material:

adding sodium acetate into pure water, heating to 65-100 ℃, adding titanium oxide mesoporous nano microspheres after the sodium acetate is completely dissolved, stirring for 10-20 minutes, cooling to room temperature, filtering, separating and precipitating, washing, then adding ethanol, stirring, adding a light absorbent, stirring for 20-30 minutes, standing for 40-100 minutes, filtering, collecting precipitate, and drying to obtain a titanium oxide nano material coated with the light absorbent; wherein the mass ratio of the sodium acetate to the titanium oxide is (0.1-0.9): 1; the mass ratio of the light absorbent to the titanium oxide is (0.2-0.9): (0.5-3.0); the mass ratio of the sodium acetate, the pure water and the ethanol is (5-10): 100: (100-180);

b. preparing polyurethane/light absorbent/titanium oxide nano composite microspheres:

b, adding the titanium oxide nano material coated with the light absorbent prepared in the step a and an isocyanate monomer compound into a butyl acetate solvent, uniformly stirring, and then sequentially adding an alcohol compound and tween 80; wherein the mass ratio of the titanium oxide nano material coated by the light absorbent, the isocyanate monomer compound, the alcohol compound, the Tween 80 and the butyl acetate solvent is as follows: (0.5-1.2): (0.4-0.9): (0.4-0.5): (1.0-2.0): (300-500); keeping the temperature at 15-25 ℃, and carrying out prepolymerization reaction for 40-60min under stirring to obtain a prepolymer solution; adding a chain extender and a catalyst into the prepolymer solution, wherein the mass ratio of the chain extender to the catalyst to the isocyanate monomer compound is (5-10): (0.2-0.5): (9-15), heating to 45-90 ℃, stirring, carrying out polymerization chain extension reaction for 10-20min, generating polyurethane coating precipitate, filtering, washing and drying the precipitate to obtain the polyurethane/light absorber/titanium oxide nano composite microspheres.

5. The blue-light/color change prevention dual-function coating optical material as claimed in claim 4, wherein the alcohol compound is a mixture of n-butanol and polytetrahydrofuran ether glycol, and the mass ratio of n-butanol to polytetrahydrofuran ether glycol is (1-3): (9-11);

the chain extender is ethylene glycol;

the catalyst is dibutyltin dilaurate;

the sodium acetate is anhydrous sodium acetate and sodium acetate trihydrate.

6. The blue light/discoloration resistant dual function coated optical material of any one of claims 1-5, wherein said blue light resistant coating is applied by a method comprising the steps of:

A. preparation of blue light prevention coating liquid

The blue light prevention coating liquid comprises the following three components:

(1) a component A:

60-75 parts by weight of polythiourethane monomer

2-9 parts by weight of polyurethane/light absorbent/titanium oxide nano composite microspheres

(2) B, component B:

10-26 parts by weight of an isocyanate-based curing agent

(3) C, component C:

8-30 parts by weight of diluent

Adding polythiourethane monomer, polyurethane/light absorbent/titanium oxide nano composite microspheres into a container according to the proportion, uniformly stirring for 15-30 minutes at room temperature to obtain a component A, and uniformly mixing the component A, the component B and the component C according to the proportion;

B. the viscosity is adjusted by a thinner, and then the coating layer is formed by coating on the surface of the optical substrate, and the coating layer is cured by room temperature, light irradiation, or heating, to prepare the blue light prevention coating layer.

7. The blue light/discoloration resistant dual function coated optical material of claim 6, wherein said blue light resistant coating is applied by a method comprising the steps of:

I. preparing coating liquid of three components A, B and C;

II, during coating, uniformly mixing the component A, the component B and the component C in proportion, and adding a diluent to adjust the viscosity to be 20-350 cp at normal temperature to obtain a blue-light-proof coating liquid;

optical substrate pretreatment: subjecting an optical substrate to one or more of the following pre-treatments: chemical treatment with alkaline aqueous solution or acidic aqueous solution, grinding treatment, plasma treatment with different air pressures, corona discharge treatment, UV ozone treatment and hardening treatment;

IV, coating: and (3) spraying or dip-coating the optical substrate after pretreatment by using the blue-light-proof coating liquid prepared in the step (II) to form a blue-light-proof coating on the substrate, thus obtaining the blue-light-proof optical material.

8. The blue light/discoloration resistant dual function coated optical material according to claim 7, wherein said step IV employs a dip coating process, which is specifically performed as follows: immersing the pretreated optical base material into the blue-light-proof coating liquid, immersing for 3-5 minutes at room temperature, slowly lifting the optical base material out of the coating liquid, moving to an oven, setting the temperature at 35-65 ℃, and baking for 45-90 minutes to form a first blue-light-proof coating; and then immersing the optical base material into the blue-light-proof coating liquid again, immersing for 3-5 minutes at room temperature, slowly lifting the optical base material out of the coating liquid, moving the optical base material into an oven, setting the temperature at 35-65 ℃, and baking for 45-90 minutes to form a second blue-light-proof coating, so as to obtain the blue-light-proof optical material.

9. The blue light/color change resistant dual function coated optical material as claimed in claim 6, wherein the polythiourethane monomer is at least one of 2, 2' -dimercaptoethylthioethane, 2, 3-dimercaptoethylthiopropanethiol, or 1,2, 3-trimercaptoethylthiopropane.

10. The blue light/discoloration preventing dual-functional coated optical material according to claim 6, wherein said isocyanate-based curing agent is at least one of a toluene diisocyanate curing agent, a diphenylmethane-4, 4' -diisocyanate curing agent, a 1, 6-hexamethylene diisocyanate curing agent, an m-xylylene diisocyanate curing agent, a methylcyclohexyl diisocyanate curing agent and an isophorone diisocyanate curing agent.

11. The blue/color change resistant dual function coated optical material as claimed in claim 6, wherein the diluent is at least one of dichloromethane, butyl acetate, methyl acetate, ethanol, butanol, acetone, toluene, xylene, diethyl ether and polytetrahydrofuran ether glycol.

12. The blue light/color change resistant dual function coated optical material according to claim 1, wherein the optical substrate is optical glass, optical plastic or optical crystal, and the thickness of the blue light resistant coating is 10 to 100 μm.

13. A method for preparing a blue light/discoloration resistant dual function coated optical material as claimed in any one of claims 1 to 12, wherein one of the following two schemes can be selected:

the first scheme is as follows: coating the blue-light-proof coating liquid, and coating a photochromic coating after completely curing;

scheme II: the front surface of the marked optical substrate is a light contact surface firstly, the back surface of the marked optical substrate is a back light contact surface, the front surface is coated with a photochromic coating, and the back surface is coated with a blue-light-proof coating.

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