CN106629793B - A kind of hollow rodlike MgF2The preparation method of particle and its application in automatically cleaning antireflective film - Google Patents

Abstract

The invention belongs to field of inorganic material preparing technology, more particularly to a kind of hollow rodlike MgF₂The preparation method of particle and its application in automatically cleaning antireflective film utilize the hollow rodlike MgF₂Particle and SiO₂After particle is compound, lifting infusion process is coated with thin film, obtain having after 250 DEG C of drying super-hydrophobicity, in visible-range highest light transmittance up to more than 97% automatically cleaning antireflective film.

Description

A kind of hollow rodlike MgF2The preparation method of particle and its in automatically cleaning antireflective film Using

Technical field

The invention belongs to field of inorganic material preparing technology, more particularly to a kind of hollow rodlike MgF₂The preparation method of particle and its Application in automatically cleaning antireflective film.

Background technology

The efficiency that solar energy is converted into heat or electric energy by light is always the important evaluation index of Solar use, and converts effect The size of rate and the transmitance height of sunlight have direct relationship.An important component part is in solar energy system The glass cover-plate on solar energy surface plays the role of solar components support protection.And applied to outdoor solar energy system Glass cover plate surfaces in system frequently suffer from the dust pollution in external environment, and the light transmittance of glass is caused drastically to decline, is reduced The utilization ratio of solar energy.Although artificial cleaning can solve the pollution problem of glass surface to a certain extent, real The solar components of border application usually have great work area, and to complete whole surface clean work becomes hardly may be used Energy.In addition, the multiple wiping of glass surface easily generates cut, certain influence can also be generated to its light transmittance.Therefore, how Prepare a kind of multifunctional glass surface antireflective film, make its also had both under the premise of visible region keeps high transmittance it is outstanding from Clean-up performance has very big practical application meaning.

When the water contact angle on surface is more than 150 ° and angle of lag is less than 5 °, then the surface is defined as super hydrophobic surface. Since super hydrophobic surface can keep drop to play automatically cleaning in freely sliding for surface so as to which the spot that surface is adhered to be taken away Effect, thus in the past few decades between cause a large amount of concern.With going deep into for research, it has been found that this surface surpasses Hydrophobicity has a very large relationship with its surface texture and chemical composition.By taking lotus leaf as an example, there is well-bedded number on surface Hundred nanometers of even micron-sized hierarchical organizations, and it has been covered with a large amount of mastoid process on the surface of each structural unit, it is this The groove being made of a large amount of protrusions can effectively be wrapped in air, so as to avoid sprawling completely for water droplet.Certainly, only this Kind coarse structure can't explain the super-hydrophobicity of lotus leaf completely, further investigation revealed that, it is also distributed on the surface of mastoid process One layer of hydrophobicity wax, forms the hydrophobic nature surface being combined by physical arrangement and chemical composition.

Invention content

The present invention provides a kind of hollow rodlike MgF₂The preparation method of particle and its application in automatically cleaning antireflective film,

Hollow rodlike MgF₂The preparation method of particle is：By magnesium acetate 4 hydrate C₄H₁₄MgO₈Solid is added to anhydrous CH₃It in OH, stirs to solid and is completely dissolved, as dispersion liquid A；HF solution is added to anhydrous CH₃In OH, it is uniformly mixed, as Dispersion liquid B；Dispersion liquid B is added drop-wise in dispersion liquid A later, and the mixed system hydro-thermal reaction to obtaining, cools down, finally obtain Hollow rodlike MgF₂The colloidal sol of particle,

Magnesium acetate, HF, total CH₃The molar ratio of OH is 1：2：250,

The time of hydro-thermal reaction is 24 hours, and reaction temperature is 240 DEG C.

Above-mentioned hollow rodlike MgF₂Application of the particle in automatically cleaning antireflective film is to utilize the hollow rodlike MgF₂Particle with SiO₂The compound structure automatically cleaning antireflective film of particle, processing step are：

(1) solid SiO₂The preparation of nanoparticle sol

With tetraethyl orthosilicate (TEOS), H₂O, absolute ethyl alcohol (EtOH), ammonium hydroxide (NH₄OH) according to traditionalWater The SiO that solution preparation structure is regular, size is controllable₂Nanoparticle sol,

By EtOH, H₂O, TEOS and NH₄OH mixing after 30 DEG C in thermostat water bath it is closed stirring 6 hours, at 30 DEG C Constant temperature is aged 3 days, and obtained blue and white colloidal sol is placed in draught cupboard, and except ammonia, (the pH test paper of moistening is close to rim of a cup for opening stirring Surface represents that ammonia has eliminated in colloidal sol so that test paper is non-discolouring whithin a period of time), obtain solid SiO₂Nanoparticle sol,

Wherein, molar ratio EtOH：TEOS：NH₄OH=114：1：3.24~5.45, it, can by controlling the addition of ammonium hydroxide To obtain the solid SiO of different-grain diameter₂Nanoparticle sol；

(2) by solid SiO preparation-obtained in step (1)₂Nanoparticle sol is configured to SiO₂Mass fraction is 1.0%~1.6% solution, and its pH value is adjusted between 1.5~2.5；Then above-mentioned be prepared is added in into the solution Hollow rodlike MgF₂The colloidal sol of particle simultaneously stirs evenly, and obtains mixed sols,

Control the MgF added in₂Particle is solid SiO in solution₂The 10%~60% of nano-particle weight；

(3) plated film is lifted in glass surface using the mixed sols obtained in step (2), after being dried under room temperature (25 DEG C), Heat cure obtain visible light wave range average transmittance up to more than 97%, there is the multi-functional antireflective film of automatically cleaning super-hydrophobicity,

Wherein, lift plated film when select light transmittance for 90% glass, pull rate between 667~5000 μm/s,

Thermosetting is turned to keeps the temperature 2h at 250 DEG C；

As preferred：The antireflective film obtained after step (3) heat cure is modified with organosilan, specially：By hexadecane Base trimethoxy silane adds in the solution for being configured to that Solute mass fraction is 5% in ethyl alcohol, then antireflective film is impregnated wherein 24 It is dry after hour.

The present invention introduces hollow rodlike MgF during automatically cleaning antireflective film is built₂Particle is assigned using its hollow-core construction The refractive index that antireflective film is lower has been given, has made the antireflective film of structure there is higher light transmittance；Using its club shaped structure in the coating Irregular protrusion construct the suitable roughness of antireflective film, reach super-hydrophobic self-cleaning effect after organosilan processing.It prepared Anti-reflection film-strength is ensured that without high-temperature calcination, optical effect caused by avoiding high-temperature process possibility is deteriorated in journey.

Description of the drawings

Fig. 1 is hollow rodlike MgF prepared in embodiment 1₂The TEM figures of particle.

Fig. 2 is the solid silicon dioxide granule of grain size 100nm and the hollow rodlike MgF of different proportion in embodiment 1₂Grain Son is surveyed according to the construction method in the present invention, the automatically cleaning antireflective film of compound structure with ultraviolet-visible-near infrared spectrometer The contrast schematic diagram of the light transmittance tried.

Fig. 3 is the solid silicon dioxide granule of grain size 50nm and the hollow rodlike MgF of different proportion in embodiment 2₂Particle According to the construction method in the present invention, the automatically cleaning antireflective film of compound structure is tested with ultraviolet-visible-near infrared spectrometer The contrast schematic diagram of the light transmittance arrived.

Specific embodiment

Embodiment 1

Control magnesium acetate 4 hydrate, HF, total CH₃The molar ratio of OH is 1：2：250, by magnesium acetate 4 hydrate C₄H₁₄MgO₈Solid is added to anhydrous CH₃It in OH, stirs to solid and is completely dissolved, as dispersion liquid A；HF solution is added to nothing Water CH₃In OH, it is uniformly mixed, as dispersion liquid B；Dispersion liquid B is added drop-wise in dispersion liquid A later, and the mixture that will be obtained System is transferred in the hydrothermal reaction kettle of polytetrafluoroethylene (PTFE), and for 240 DEG C of hydro-thermals after 24 hours, solution is taken out in cooling, obtains hollow rodlike MgF₂The colloidal sol of particle.

After testing, the hollow rodlike MgF in above-mentioned colloidal sol₂The specific pattern of particle is as shown in Figure 1.

(1) 60ml EtOH, 1ml H are added in into the beaker of 100ml₂O、3ml NH₄OH, 2.3ml TEOS are with after constant temperature In water-bath 30 DEG C it is closed stirring 6 hours after, at 30 DEG C constant temperature be aged 3 days；Obtained leucosol is placed in draught cupboard, is opened Except ammonia, (the pH test paper of moistening represents that ammonia is in colloidal sol right over rim of a cup with test paper is non-discolouring whithin a period of time for mouth stirring Eliminate), obtain the solid SiO of grain size 100nm₂Nanoparticle sol,

(2) by solid SiO preparation-obtained in step (1)₂Nanoparticle sol is configured to SiO₂Mass fraction is 1.3% solution, and it is 2 to adjust its pH value；Then the above-mentioned hollow rodlike MgF being prepared is added in into the solution₂Particle Colloidal sol and stir evenly, obtain mixed sols,

(3) plated film, lifting speed are lifted in the glass surface that light transmittance is 90% using the mixed sols obtained in step (2) It spends for 1500 μm/s, after dry under room temperature (25 DEG C), heat cure 2h in 250 DEG C of baking ovens, cooling obtains automatically cleaning antireflective film,

With the hollow rodlike MgF added in step (2)₂Particle is solid SiO in solution₂The 36% of nano-particle weight is Example, the water contact angle of the automatically cleaning anti-reflection film surface of preparation are less than 5 ° for 130 ° and angle of lag；

Above-mentioned automatically cleaning antireflective film after cooling is immersed into the ethyl alcohol that hexadecyl trimethoxy silane mass fraction is 5% 24 hours in solution, processed automatically cleaning antireflective film is dried to obtain,

Hollow rodlike MgF equally to be added in step (2)₂Particle is solid SiO in solution₂Nano-particle weight For 36%, the water contact angle of the automatically cleaning anti-reflection film surface of preparation is less than 5 ° for 152 ° and angle of lag, and anti-reflection film strength reaches To pencil hardness 4H.

Above-mentioned steps pass through the MgF to addition in (2)₂Particle and solid SiO in solution₂The weight ratio of nano-particle carries out Adjustment, as shown in Figure 2, antireflective film is in visible light wave range average transmittance up to 97% for the light transmittance of the automatically cleaning antireflective film of structure More than.

Comparative example 1

Completely using the solid silica plated film prepared in embodiment 1, remaining operation is the same as embodiment 1：

(1) 60ml EtOH, 1ml H are added in into the beaker of 100ml₂O、3ml NH₄OH, 2.3ml TEOS are with after constant temperature In water-bath 30 DEG C it is closed stirring 6 hours after, at 30 DEG C constant temperature be aged 3 days；Obtained leucosol is placed in draught cupboard, is opened Except ammonia, (the pH test paper of moistening represents that ammonia is in colloidal sol right over rim of a cup with test paper is non-discolouring whithin a period of time for mouth stirring Eliminate), obtain the solid SiO of grain size 100nm₂Nanoparticle sol；

(2) by solid SiO preparation-obtained in step (1)₂Nanoparticle sol is configured to SiO₂Mass fraction is 1.3% solution, and it is 2 to adjust its pH value, and it is lifted plated film in the glass surface that light transmittance is 90%, pull rate is 1500 μm/s, after dry under room temperature (25 DEG C), heat cure 2h in 250 DEG C of baking ovens, cooling obtains antireflective film, the anti-reflection film surface Water contact angle is 54 °；

Above-mentioned antireflective film after cooling is immersed into the ethanol solution that hexadecyl trimethoxy silane mass fraction is 5% again In 24 hours, be dried to obtain processed antireflective film, the water contact angle on surface is 80 °.

Comparative example 2

Compared with Example 1, after the heat cure of step (3), then the antireflective film handled 2 hours at 400 DEG C, remaining Operation is the same as embodiment 1.

With the hollow rodlike MgF added in step (2)₂Particle is solid SiO in solution₂The 36% of nano-particle weight is Example, is handled through hexadecyl trimethoxy silane and dried anti-reflection film strength is still pencil hardness 4H.

Comparative example 3

Compared to embodiment 1, MgF will be prepared₂" magnesium acetate 4 hydrate, HF, total CH during particle₃Mole of OH Than " it is revised as 1：2.2：250, remaining step is the same as embodiment 1.The MgF prepared at this time₂Particle is similar to hollow spherical particles.

Automatically cleaning antireflective film is prepared according to the method in embodiment 1, with the hollow MgF added in step (2)₂Particle is molten Solid SiO in liquid₂For the 36% of nano-particle weight, the antireflective film being prepared is at through hexadecyl trimethoxy silane The front and rear surface water contact angle of reason is respectively 67 ° and 98 °.

Comparative example 4

Compared to embodiment 1, MgF will be prepared₂" 240 DEG C hydro-thermal 24 hours " during particle are revised as " 175 DEG C of hydro-thermals 32 hours ", remaining step is the same as embodiment 1.The MgF prepared at this time₂Particle is similar to solid rod-shpaed particle.

Automatically cleaning antireflective film is prepared according to the method in embodiment 1, with the solid rodlike MgF added in step (2)₂Particle For SiO solid in solution₂For the 36% of nano-particle weight, the antireflective film that is prepared is in the average transmittance of visible light wave range Rate is 92%, is being respectively 109 ° and 135 ° through the surface water contact angle of hexadecyl trimethoxy silane before and after the processing.

Embodiment 2

Hollow rodlike MgF₂The preparation process of particle is the same as embodiment 1.

(1) 114ml EtOH, 2ml H are added in into the beaker of 250ml₂O、7.12ml NH₄OH, 3.8ml TEOS with after In thermostat water bath 30 DEG C it is closed stirring 6 hours after, at 30 DEG C constant temperature be aged 3 days；Obtained leucosol is placed in draught cupboard In, except ammonia, (the pH test paper of moistening is represented so that test paper is non-discolouring whithin a period of time in colloidal sol right over rim of a cup for opening stirring Ammonia has eliminated), obtain the solid SiO of grain size 50nm₂Nanoparticle sol；

(2) technique is with embodiment 1,

(3) technique is the same as embodiment 1.

Step passes through the MgF to addition in (2)₂Particle and solid SiO in solution₂The weight ratio of nano-particle is adjusted, The light transmittance of the automatically cleaning antireflective film of structure is as shown in Figure 3.

Claims (8)

1. a kind of hollow rodlike MgF₂The preparation method of particle, it is characterised in that：The preparation method is, by four water of magnesium acetate Close object C₄H₁₄MgO₈Solid is added to anhydrous CH₃It in OH, stirs to solid and is completely dissolved, as dispersion liquid A；HF solution is added in To anhydrous CH₃In OH, it is uniformly mixed, as dispersion liquid B；Dispersion liquid B is added drop-wise in dispersion liquid A later, and mixed to what is obtained Zoarium system hydro-thermal reaction, cooling, finally obtains hollow rodlike MgF₂The colloidal sol of particle,

Wherein, magnesium acetate, HF, total CH₃The molar ratio of OH is 1：2：250,

The time of hydro-thermal reaction is 24 hours, and reaction temperature is 240 DEG C.

2. a kind of hollow rodlike MgF that method as described in claim 1 is prepared₂The application of particle, it is characterised in that：It utilizes The hollow rodlike MgF₂Particle and SiO₂The compound structure automatically cleaning antireflective film of particle.

3. hollow rodlike MgF as claimed in claim 2₂The application of particle, it is characterised in that：The construction method is,

(1) solid SiO₂The preparation of nanoparticle sol；

(2) by solid SiO preparation-obtained in step (1)₂Nanoparticle sol is configured to solution, and adjusts its pH value；Then The hollow rodlike MgF of gained is added in into the solution₂The colloidal sol of particle, is uniformly mixing to obtain mixed sols；

(3) plated film is lifted in glass surface using the mixed sols obtained in step (2), after being dried under room temperature, heat cure.

4. hollow rodlike MgF as claimed in claim 3₂The application of particle, it is characterised in that：The concrete operations of step (1) are, By EtOH, H₂O, TEOS and NH₄OH mixing is stirred 6 hours after closed in thermostat water bath, and constant temperature is aged 3 days at 30 DEG C, Obtained blue and white colloidal sol is placed in draught cupboard, opening stirring obtains solid SiO except ammonia₂Nanoparticle sol.

5. hollow rodlike MgF as claimed in claim 3₂The application of particle, it is characterised in that：In step (2), solution is configured Mass fraction be 1.0%~1.6%.

6. hollow rodlike MgF as claimed in claim 3₂The application of particle, it is characterised in that：In step (2), the MgF of addition₂ Particle is solid SiO in solution₂The 10%~60% of nano-particle weight.

7. hollow rodlike MgF as claimed in claim 3₂The application of particle, it is characterised in that：In step (3), when lifting plated film Selecting light transmittance, pull rate is between 667~5000 μm/s for 90% glass.

8. hollow rodlike MgF as claimed in claim 3₂The application of particle, it is characterised in that：In step (3), thermosetting turns to 2h is kept the temperature at 250 DEG C.