CN100353187C - Antiglare film - Google Patents
Antiglare film Download PDFInfo
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- CN100353187C CN100353187C CNB2005800003193A CN200580000319A CN100353187C CN 100353187 C CN100353187 C CN 100353187C CN B2005800003193 A CNB2005800003193 A CN B2005800003193A CN 200580000319 A CN200580000319 A CN 200580000319A CN 100353187 C CN100353187 C CN 100353187C
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Abstract
An antiglare mirror which has a light-diffusing layer being composed of a transparent resin phase and fine resin particles dispersed in the resin phase, wherein said fine resin particles comprise fine spherical resin particles and fine bowl-like resin particles having concave central portions, and the refractive index (nx) of the transparent resin phase and the refractive index (nz) of fine bowl-like resin particles satisfy the relationship of the following formula (1): nx - nz >= 0.03 (1). The light-diffusing layer may be provided on one surface of a transparent substrate, and a concave-convex surface of the light-diffusing layer preferably has an average roughness (Ra) of 0.1 to 1.0 mum.
Description
Technical field
The invention relates to the anti-dazzle film of the surface elements that can be applicable to various ligthing paraphernalias or various displays, particularly about in LCD etc., have anti-dazzle property, and can prevent anti-dazzle film image blurring, that prevent to glitter and prevent to produce white portion by surface scattering.
Background technology
With LCD, plasma display, CRT (cathode-ray tube (CRT)), EL (electroluminescence) etc. is the image display device (following these are called " display ") of representative, just in various fields such as televisor and computing machine, use, and obtain alarming development.LCD particularly as thin, light weight and be rich in the display of versatility, as the display media that slim TV mobile phone, PC, digital camera, PDA, other various devices are used, is popularized significantly.
When these displays are used in outdoor or the inferior brighter place of fluorescent light, can become problem by what exterior light such as sunshine or fluorescent light caused to mirroring of display, in order to prevent this problem, generally be to implement non-glare treated, form concavo-convexly at display surface, make the exterior light generation diffuse reflection of mirroring.
This non-glare treated can be undertaken by following processing: by sandblast etc. display surface is formed uneven surface, or behind display surface coating transparent resin, the irregular excipient film of apparatus carries out excipient to be handled, or, antiglare layer etc. is set at display surface by being coated on the coating that disperses inorganic or organic transparent particulate to form in the resin binder.
In these technology, the use resin binder of enumerating at last and the non-glare treated of organic transparent particulate, concavo-convex by what form by particulate, the refringence of resin binder and particulate can make exterior light generation scattering, and then, when being applied to generally from its mechanism restricted LCD in visual angle, by the image information from display is penetrated in the wide range scattering, also can expect the expansion effect at visual angle, therefore it is just becoming the most frequently used method now, for example at No. 3314965 communique instructions of special permission, Te Kaiping 5-162261 communique, open in the Te Kaiping 7-181306 communique etc.
Summary of the invention
But, implement the display of non-glare treated for using above-mentioned resin binder and organic transparent particulate, when suppressing the mirroring of surface, from the image information of display interior scattering takes place inadvertently also, thereby exist image blurring or such problem of glittering.In addition, because exterior light, the non-glare treated surface of display also can produce the so-called white of turning white that becomes and partly generate such phenomenon.And then when display was LCD, the problem of existence was, viewing angle characteristic can worsen, if look side ways shown image, then contrast can reduce, and sees that image fades.
The present invention is that purpose is finished to solve the aforementioned problems in the prior, and its purpose is to provide the anti-dazzle film of the non-glare treated of the deterioration that is applicable to the viewing angle characteristic that suppresses the fuzzy of image or the generation of glittering, suppresses LCD.
The inventor has carried out research with keen determination in order to address the above problem, and found that, by using refractive index to have the transparent resin and the bowl-shape resin particle of particular kind of relationship simultaneously with the spherical shape resin particle, can realize above-mentioned purpose, thereby finish the present invention.
Promptly, anti-dazzle film of the present invention be have resin particle be dispersed in transparent resin mutually in and the anti-dazzle film of the light diffusion layer that constitutes, it is characterized in that resin particle constitutes the refractive index n of transparent resin phase by the bowl-shape resin particle that the central portion of spherical shape particulate and particle caves in into concavity at least
xRefractive index n with bowl-shape resin particle
zSatisfy the relation of following formula (1).
n
x-n
z≥0.03 (1)
For above-mentioned anti-dazzle film of the present invention, the refractive index n of preferred spherical shape resin particle
yRefractive index n with bowl-shape resin particle
zSatisfy the relation of following formula (2).
n
z<n
y (2)
In addition, for above-mentioned anti-dazzle film of the present invention, the mean grain size D of preferred spherical shape resin particle
yBe 0.3 μ m~7.0 μ m, the mean grain size D of bowl-shape resin particle
zBe respectively 0.3 μ m~7.0 μ m, and then the mean grain size D of preferred spherical shape resin particle
yMean grain size D with bowl-shape resin particle
zSatisfy the relation of following formula (3).
0.7D
z≤D
y≤1.4D
z (3)
For anti-dazzle film of the present invention, above-mentioned light diffusion layer preferably is arranged on the one side at least of transparent base.
In addition, above-mentioned light diffusion layer preferably has convex-concave surface, and the protuberance of this convex-concave surface is formed by the protuberance of spherical shape resin particle and bowl-shape resin particle.At this moment, preferably the height than above-mentioned bowl-shape resin particle is thick for the thickness of the thinnest portion of light diffusion layer.In addition, 110~300% of the preferably above-mentioned bowl-shape resin particle height of the mean grain size of above-mentioned spherical shape resin particle.And then the average roughness Ra of above-mentioned convex-concave surface is 0.1~1.0 μ m preferably.
Anti-dazzle film of the present invention can suppress image blurring effect owing to use spherical shape resin particle and bowl-shape resin particle when therefore can produce the visual angle that enlarges display.Promptly, the peculiar shape of bowl-shape resin particle is compared with the spherical shape resin particle, has the effect that the scattering of light is limited in specific direction, therefore because the existence of bowl-shape resin particle can suppress image blurring effect when can give play to the visual angle that enlarges display.
In addition, in general, for the film that has carried out non-glare treated, owing to play the effect of lens by the concavo-convex of the formed anti-dazzle film of particulate surface and the interface of transparent resin phase that has different refractive indexes separately and particulate, can produce the power of local luminance on the anti-dazzle film surface, glitter thereby produce, but for anti-dazzle film of the present invention, in light diffusion layer, form transparent resin phase-spherical shape resin particle and transparent resin mutually-2 kinds of interfaces of bowl-shape resin particle, the latter particularly, have the index of refraction relationship shown in the above-mentioned formula (1), therefore can eliminate lensing, eliminate the effect of glittering thereby produce at each interface.In addition, also can produce the concavo-convex effect of glittering that cause of elimination by the anti-dazzle film surface.
In addition; for the film that has carried out non-glare treated; if the anti-dazzle film surface that is formed by particulate is concavo-convex big; then can produce white portion; on the other hand; if it is concavo-convex little; then there is the inadequate problem of anti-dazzle property that mirrors that suppresses exterior light; but for anti-dazzle film of the present invention; the protuberance of convex-concave surface only has by spherical shape resin particle or the peculiar concave-convex surface shape that formed by spherical shape resin particle and bowl-shape resin particle, and the effect of the anti-dazzle property of appropriateness is given in performance when therefore can suppress white portion and produce.
Therefore, anti-dazzle film of the present invention can be applied to the surface elements of various ligthing paraphernalias or various displays, and particularly going for LCD, plasma display, CRT, EL etc. is the image display device of representative.
Description of drawings
Fig. 1 is the pattern sectional view of an example of anti-dazzle film of the present invention.
Fig. 2 is another routine pattern sectional view of anti-dazzle film of the present invention.
Fig. 3 is the pattern sectional view of the another example of anti-dazzle film of the present invention.
Fig. 4 is the vertical view of the bowl-shape resin particle that uses among the present invention.
Fig. 5 is the side cross-sectional view of the bowl-shape resin particle that uses among the present invention.
Symbol description
1 ... transparent resin phase, 2 ... spherical shape resin particle, 3 ... bowl-shape resin particle, 4 ... light diffusion layer, 5 ... transparent base, Dz ... mean grain size, a ... bore, b ... thickness, h ... highly.
Embodiment
The embodiment of anti-dazzle film of the present invention is described with reference to accompanying drawing.
Fig. 1 is the pattern sectional view of an example of anti-dazzle film of the present invention.It has by spherical shape resin particle 2 and bowl-shape resin particle 3 and is dispersed in transparent resin mutually in 1 and the light diffusion layer 4 that forms, and forms the protuberance of convex-concave surfaces by spherical shape resin particle 2.In addition, Fig. 2 is another routine pattern sectional view of anti-dazzle film of the present invention, and for the situation of this figure, above-mentioned light diffusion layer shown in Figure 14 is arranged on the transparent base 5 as coating layer, thereby forms anti-dazzle film.Fig. 3 is the pattern sectional view of the another example of anti-dazzle film of the present invention, situation for this figure, in the light diffusion layer 4 on being arranged on transparent base 5, bowl-shape resin particle 3 is dispersed in the transparent resin phase 1 brokenly, forms the protuberance of convex-concave surfaces by spherical shape resin particle 2 and bowl-shape resin particle 3.
As the resin particle that in anti-dazzle film of the present invention, uses, can use various resin particles such as its material, shape, particle diameter.Material as such resin particle, for example can enumerate acrylic resin, silicone resin, styrene resin, melamine resin, styrene-propene acid copolymer resin etc., can be according to as the needed refractive index of light diffusion layer, the compatibility of bonding agent etc. be freely selected.In addition, be purpose to improve dispersed and to control refractive index, also can utilize organic-inorganic materials such as grease class, silane coupling agent, metal oxide to carry out surface treatment.
In the present invention, the part of above-mentioned resin particle is the spherical shape resin particle, and other at least a portion is that the bowl-shape resin particle that central portion caves in into concavity is necessary.In the present invention, so-called spherical shape resin particle is meant that its shape is a ball or near the spheroidal particle of ball, the spherical shape resin particle that for example can use the suspension polymerization by monomer, the spray drying process of polymer solution etc. to make.
In addition, bowl-shape resin particle still is typically the bowl-shape resin particle with Fig. 4 and shape shown in Figure 5 so long as the resin particle that has the form of recess as bowl just has no particular limits.Fig. 4 is the vertical view of bowl-shape resin particle, and Fig. 5 is a side cross-sectional view, in the present invention, and the mean grain size D shown in the figure preferably
z, bore a, thickness b and height h relation satisfy the shape of the relation of following formula.
0<a<D
z, more preferably 0.2D
z<a<0.8D
z
0<b<0.75D
z, more preferably 0.1D
z<b<0.5D
z
0.1D
z<h<D
z, more preferably 0.25D
z<h<0.75D
z
In addition, for anti-dazzle film of the present invention, the mean grain size D of spherical shape resin particle
yWith bowl-shape resin particle D
zAll preferred scope at 0.3~7.0 μ m.If the mean grain size of these particulates less than 0.3 μ m, then owing to become littler than visible wavelength, therefore can not get good light diffusing, on the other hand, if surpass 7.0 μ m, then can present the granular sense of resin particle on the anti-dazzle film surface, therefore also not preferred.
And then, for anti-dazzle film of the present invention, the mean grain size D of spherical shape resin particle
yPreferably 110~300% of the height h of bowl-shape resin particle.Mean grain size D
yIf greater than 300% of height h, then concave-convex surface becomes big, can produce white portion, and on the other hand, if less than 110%, then concavo-convex meeting diminishes, and the effect that suppresses the anti-dazzle property that mirrors of exterior light becomes insufficient.In addition, the value of the above-mentioned shape of particle among the present invention is to utilize electron microscope to observe the value of obtaining by shape.
In addition, about the above-mentioned spherical shape resin particle that contains in the anti-dazzle film of the present invention and the number of above-mentioned bowl-shape resin particle, also the particle diameter according to employed particulate changes, and therefore has no particular limits, but is preferably set to smaller or equal to 60000/mm
2, be more preferably less than and equal 40000/mm
2, especially preferably smaller or equal to 20000/mm
2, and more than or equal to 5000/mm
2Scope.
And then, about the above-mentioned spherical shape resin particle that contains in the anti-dazzle film of the present invention and the cooperation ratio of above-mentioned bowl-shape resin particle, have no particular limits, but the scope of the number of the number of spherical shape resin particle/bowl-shape resin particle=50/50~1/99 preferably, special preferably 40/60~2/98 scope.
In anti-dazzle film of the present invention, the transparent resin as constituting the transparent resin phase of disperseing above-mentioned resin particle can use thermoplastic resin, thermoset resin, radiation-curing type resin etc. aptly.
As thermoplastic resin, can use polyethylene terephthalate (PET), PEN (PEN), polymethylmethacrylate (PMMA), polycarbonate (PC), tygon (PE), polypropylene (PP), polyvinyl alcohol (PVA) (PVA), Polyvinylchloride (PVC), cyclenes copolymer (COC), contain various resins such as norbornene resin, polyethersulfone.
As radiation-curing type resin, can use the composition of the monomer that mixed polymerism unsaturated links such as having acryloyl group, methacryl, acryloxy, methacryloxy, epoxy radicals, vinyl ether, oxetanyl or functional group similar aptly, oligomer, prepolymer with it.As the example of monomer, can enumerate methyl acrylate, methyl methacrylate, methoxyl polymethyl vinyl acetate, cyclohexyl methacrylate, methacrylic acid phenoxy ethyl, ethylene glycol dimethacrylate, two dipentaerythritol acrylates, trimethylol-propane trimethacrylate etc.As oligomer and prepolymer, can enumerate polyester acrylate, urethane acrylate, epoxy acrylate, polyether acrylate, the alkyd acrylate, the melamine acrylate, acrylate compounds such as silicone acrylate, unsaturated polyester (UP), butanediol diglycidyl ether, propylene glycol diglycidylether, neopentylglycol diglycidyl ether, bisphenol A diglycidyl ether, epoxy compounds such as various ester ring type epoxies, 3-ethyl-3-hydroxymethyl oxetanes, 1, two { [(3-ethyl-3-oxetanyl) methoxyl] methyl } benzene of 4-, oxetane compounds such as two [1-ethyl (3-oxetanyl)] methyl ether.These materials can use separately, perhaps mix multiple use.
As thermoset resin, can enumerate phenolics, furane resin, xylene formaldehyde resin, ketone formaldehyde resin, Lauxite, melamine resin, anline resin, alkyd resin, unsaturated polyester resin, epoxy resin etc.These resins can separately or mix multiple and use.
For the transparent resin that uses in the anti-dazzle film of the present invention, the transparency is high more good more, and light transmittance (JIS K-7105) is more than or equal to 80%, preferably more than or equal to 90%.Even light transmittance less than 80% is also no problem for the present invention, still the film meeting deepening of using as display is therefore also imperfect.
In addition, the transparent resin that constitutes by these transparent resins mutually in, in order to give various characteristics, also can add the particulate of the nano-scale that does not influence the light diffusion as modifier.As its example, can enumerate silicon dioxide, titania, silicate sol, titanate colloidal sol, ITO, ATO etc.
The light diffusion layer of anti-dazzle film of the present invention can be by making the dissolving of above-mentioned transparent resin and spherical shape resin particle and bowl-shape resin particle, being dispersed in the appropriate solvent, is coated on the suitable matrix then and carries out drying, be solidified to form.In the present invention, light diffusion layer can be peeled off from matrix, can be provided with the coating layer form on the transparent base.
The thickness of light diffusion layer is the scope of 0.5~200 μ m preferably.In addition, light diffusion layer is the situation that is coated on the coating layer on the transparent base, and light diffusion layer is supported by transparent base, so its thickness scope of 0.5~50 μ m preferably, is more preferably the scope of 1~10 μ m.
For anti-dazzle film of the present invention, light diffusion layer is the situation that is coated on the coating layer on the transparent base, as transparent base, can use known transparent membrane, glass etc.As its object lesson, can suit to use polyethylene terephthalate (PET), PEN (PEN), triacetyl cellulose (TAC), polymethylmethacrylate (PMMA), polycarbonate (PC), polyimide (PI), tygon (PE), polypropylene (PP), polyvinyl alcohol (PVA) (PVA), Polyvinylchloride (PVC), cyclenes copolymer (COC), contain various resin films such as norbornene resin, polyethersulfone, cellophane, aromatic polyamide and quartz glass, glass baseplate such as soda-lime glass etc.When in plasma display or LCD, using anti-dazzle film of the present invention, transparent base preferably by PET, TAC, COC, contain the transparent base that norbornene resin etc. constitutes.
The transparency of these transparent bases is high more good more, and light transmittance (JIS K-7105) is more than or equal to 80%, is more preferably more than or equal to 90%.Even light transmittance less than 80% is also no problem for the present invention, but understand deepening as the film that display is used, thus and it is imperfect.
In addition, the thickness of these transparent bases has no particular limits, but 5~600 μ m preferably if consider its throughput rate, then especially preferably use the thickness of 5~200 mu m ranges.
For anti-dazzle film of the present invention, the refractive index n of above-mentioned transparent resin
xRefractive index n with bowl-shape resin particle
zNeed satisfy the relation of above-mentioned formula (1).That is, in the light diffusion layer of anti-dazzle film of the present invention, form transparent resin phase-spherical shape resin particle and transparent resin mutually-2 kinds of interfaces of bowl-shape resin particle.Wherein,, can eliminate separately effect, eliminate the effect of glittering thereby produce as lens by between transparent resin phase-bowl-shape resin particle, satisfying the relation of above-mentioned formula (1).As mentioned above, the bowl-shape resin particle that refractive index is low need be more than or equal to 0.03 with transparent resin refringence mutually, preferably more than or equal to 0.05, especially preferably more than or equal to 0.07.
In addition, for anti-dazzle film of the present invention, the refractive index n of preferred spherical shape resin particle
yRefractive index n with bowl-shape resin particle
zSatisfy the relation of above-mentioned formula (2).At this moment, though the details of reason are not clear,, can suppress to be considered to result from the bluring, glitter of white portion, image of the relation of the shape of resin particle and refractive index by satisfying the relation of above-mentioned formula (2).
In addition, for anti-dazzle film of the present invention, the particle diameter of above-mentioned spherical shape resin particle and the mean grain size of above-mentioned bowl-shape resin particle be too during big difference, is desirable aspect preventing to glitter.Specifically, the mean grain size D of spherical shape resin particle
yMean grain size D with bowl-shape resin particle
zPreferably satisfy the relation of above-mentioned formula (3).Especially preferably satisfy
0.8D
z≤ D
y≤ 1.2D
zRelation.
In anti-dazzle film of the present invention, the preferred light diffusion layer has convex-concave surface.The protuberance of convex-concave surface can only be formed by the spherical shape resin particle, but is preferably formed by spherical shape particulate and bowl-shape resin particle.In addition, situation about forming by spherical shape resin particle and bowl-shape resin particle at the protuberance of convex-concave surface, protuberance by the part of the projection of spherical shape resin particle and bowl-shape resin particle, be the protuberance of hemispherical part and the ring-type that forms at the recess edge of the recess side of bowl-shape resin particle and forming, the shape of protuberance and quantity can utilize laser microscope or SEM (scanning electron microscope) to observe.
The situation that the protuberance of convex-concave surface is formed by spherical shape resin particle and bowl-shape resin particle, the total number of the protuberance that is formed by the hemispherical part of spherical shape resin particle and bowl-shape the resin particle more preferably quantity than the protuberance of the ring-type of the recess side of bowl-shape resin particle are many.Promptly, the protuberance that is formed by the hemispherical part of spherical shape resin particle and bowl-shape resin particle is a main body, the situation of the convex-concave surface of the state that is suitably mixed by the formed protuberance of protuberance of the ring-type of the recess side of bowl-shape resin particle can be brought into play the effect that suppresses to give when white portion produces the anti-dazzle property of appropriateness.In addition, if the ratio of the protuberance that is formed by the protuberance of the ring-type of the recess side of bowl-shape resin particle increases, the ratio of then more sharp-pointed drift angle can increase on light diffusion layer surface concavo-convex, the raising of anti-dazzle property, but be easy to generate white portion.
In addition, in anti-dazzle film of the present invention, the average roughness Ra of the convex-concave surface of light diffusion layer is the scope of 0.1~1.0 μ m preferably, is more preferably the scope of 0.1~0.5 μ m.If average roughness Ra is less than 0.1 μ m, then concave-convex surface diminishes, and the anti-dazzle property effect that mirrors that suppresses exterior light can become insufficient; If greater than 1.0 μ m, then concavo-convex change is big, thereby produces white portion, and is therefore also not preferred.
In the present invention, preferably the height (h) than bowl-shape resin particle is thick for the thickness of the thinnest portion of the light diffusion layer of anti-dazzle film.If make the thickness of the thinnest portion thinner than the height of bowl-shape resin particle, then be dispersed in concavo-convex relevant that transparent resin all spherical shape resin particles in mutually and bowl-shape resin particle all can be with convex-concave surface, the concavo-convex change on anti-dazzle film surface is big, thereby produces white portion.In addition, because the concaveconvex shape on anti-dazzle film surface becomes complicated, suppress image blurring effect and can weaken.
Below, be described more specifically the present invention with embodiment, but the invention is not restricted to these embodiment.In addition, in following embodiment and comparative example, " part " is meant weight portion.
Relative 100 parts of refractive indexes as transparent resin are 1.51 (n
x) dipentaerythritol acrylate, add 3 parts of 2-hydroxy-2-methyl propiophenones, be 1.59 (n as 6 parts of refractive indexes of resin particle as light trigger
y), mean grain size is 3.0 μ m (D
y) styrene resin rounding spherical resin fine particles and 4 parts of refractive indexes be 1.42 (n
z), mean grain size is 2.4 μ m (D
z), highly be that 1.7 μ m (h), bore are that 1.8 μ m (a), thickness are the bowl-shape resin particle of silicone resin system of 0.35 μ m (b), 130 parts of methyl isobutyl ketones as solvent, by disperseing 30 minutes, obtain coating with sand mill.Using reverse coating method that the coating that obtains is coated on by thickness is that 80 μ m, transmissivity are on the transparent base that constitutes of 94% TAC, 100 ℃ of dryings after 2 minutes, carry out ultraviolet ray irradiation (irradiation distance 10cm, irradiation time 30 seconds) with 1 120W/cm light harvesting type high-pressure mercury-vapor lamp, coated film is solidified.As previously discussed, making has the anti-dazzle film that thickness is the light diffusion layer of 3.2 μ m, average roughness Ra=0.18.
Mix 100 parts of refractive indexes and be as transparent resin 1.67 contain zirconium ultraviolet hardening (UV) acrylate (trade name: Kz7391, solid component concentration is 42%, the JSR system), 18 parts of refractive indexes are 1.51 dipentaerythritol acrylate, the refractive index when obtaining solidifying is 1.61 (n
x), solid concentration is 51% transparent resin solution.Add 100 parts of these transparent resin solutions, 1 part of 2-hydroxy-2-methyl propiophenone, be 1.59 (n as 3 parts of refractive indexes of resin particle as light trigger
y), mean grain size is 3.0 μ m (D
y) styrene resin rounding spherical resin fine particles and 2 parts of refractive indexes be 1.42 (n
z), mean grain size is 2.4 μ m (D
z), highly be that 1.7 μ m (h), bore are that 1.8 μ m (a), thickness are the bowl-shape resin particle of silicone resin system of 0.35 μ m (b), 80 parts of methyl isopropyl Ketones as solvent, disperseed 30 minutes with sand mill, obtain coating.Using reverse coating method that the coating that obtains is coated on by thickness is that 80 μ m, transmissivity are on the transparent base that constitutes of 94% TAC, 100 ℃ of dryings after 2 minutes, carry out ultraviolet ray irradiation (irradiation distance is that 10cm, irradiation time are 30 seconds) with 1 120W/cm light harvesting type high-pressure mercury-vapor lamp, coated film is solidified, make anti-dazzle film.With this anti-dazzle film of electron microscope observation, results verification, the thickest portion of antiglare layer is that 3.2 μ m, the thinnest portion are 2.2 μ m, and the protuberance of convex-concave surface is formed by the spherical shape resin particle.Average roughness Ra is 0.37 μ m.
Relative 100 parts of refractive indexes as transparent resin are 1.51 (n
x) dipentaerythritol acrylate, add 3 parts of 2-hydroxy-2-methyl propiophenones, be 1.49 (n as 6 parts of refractive indexes of resin particle as light trigger
y), mean grain size is 3.0 μ m (D
y) PMMA resin rounding spherical resin fine particles and 4 parts of refractive indexes be 1.42 (n
z), mean grain size is 2.4 μ m (D
z), highly be 1.7 μ m (h), bore be 1.8 μ m (a), thickness be 0.35 μ m (
B) the bowl-shape resin particle of silicone resin system, 130 parts of methyl isopropyl Ketones as solvent disperseed 30 minutes with sand mill, obtained coating.Using reverse coating method that the coating that obtains is coated on by thickness is that 80 μ m, transmissivity are on the transparent base that constitutes of 94% TAC, 100 ℃ of dryings after 2 minutes, carry out ultraviolet ray irradiation (irradiation distance is that 10cm, irradiation time are 30 seconds) with 1 120W/cm light harvesting type high-pressure mercury-vapor lamp, coated film is solidified.As previously discussed, making has the anti-dazzle film that thickness is the light diffusion layer of 3.2 μ m, average roughness Ra=0.12.
Comparative example 1
Relative 100 parts of refractive indexes as transparent resin are 1.51 (n
x) dipentaerythritol acrylate, add 3 parts of 2-hydroxy-2-methyl propiophenones, be 1.59 (n as 6 parts of refractive indexes of resin particle as light trigger
y), mean grain size is 3.0 μ m (D
y) styrene resin rounding spherical resin fine particles and 4 parts of refractive indexes be 1.53 (n
z), mean grain size is 2.51 μ m (D
z), highly be 0.61 μ m (h), bore be 0.51 μ m (a), thickness be 0.40 μ m (
b) the bowl-shape resin particle of styrene-propene acid resin system, 200 parts of methyl isopropyl Ketones as solvent, disperseed 30 minutes with sand mill, obtain coating.Using reverse coating method that the coating that obtains is coated on by thickness is that 80 μ m, transmissivity are on the transparent base that constitutes of 94% TAC, 100 ℃ of dryings after 2 minutes, carry out ultraviolet ray irradiation (irradiation distance is that 10cm, irradiation time are 30 seconds) with 1 120W/cm light harvesting type high-pressure mercury-vapor lamp, coated film is solidified.As previously discussed, make have thickness be 3.2 μ m, average roughness Ra=0.20 light diffusion layer relatively use anti-dazzle film.
Comparative example 2
Relative 100 parts of refractive indexes as transparent resin are 1.51 (n
x) dipentaerythritol acrylate, add 3 parts of 2-hydroxy-2-methyl propiophenones, be 1.59 (n as 4 parts of refractive indexes of resin particle as light trigger
y), mean grain size is 3.0 μ m (D
y) styrene resin rounding spherical resin fine particles and 4 parts of refractive indexes be 1.49 (n
z), mean grain size is 2.41 μ m (D
z), highly be 0.61 μ m (h), bore be 0.5 μ m (a), thickness be 0.35 μ m (
b) the bowl-shape resin particle of acryl resin system, 200 parts of methyl isopropyl Ketones as solvent, disperseed 30 minutes with sand mill, obtain coating.Using reverse coating method that the coating that obtains is coated on by thickness is that 80 μ m, transmissivity are on the transparent base that constitutes of 94% TAC, 100 ℃ of dryings after 2 minutes, carry out ultraviolet ray irradiation (irradiation distance is that 10cm, irradiation time are 30 seconds) with 1 120W/cm light harvesting type high-pressure mercury-vapor lamp, coated film is solidified.As previously discussed, make have thickness be 3.5 μ m, average roughness Ra=0.09 light diffusion layer relatively use anti-dazzle film.
Comparative example 3
Relative 100 parts of refractive index 1.51 (n as transparent resin
x) dipentaerythritol acrylate, add 3 parts of 2-hydroxy-2-methyl propiophenones, be 1.59 (n as 6 parts of refractive indexes of resin particle as light trigger
y), mean grain size is 3.0 μ m (D
y) styrene resin rounding spherical resin fine particles and 4 parts of refractive indexes be 1.42 (n
z), mean grain size is 2.4 μ m (D
z) silicone resin rounding spherical resin fine particles, 130 parts of methyl isopropyl Ketones as solvent, disperseed 30 minutes with sand mill, obtain coating.Using reverse coating method that the coating that obtains is coated on by thickness is that 80 μ m, transmissivity are on the transparent base that constitutes of 94% TAC, 100 ℃ of dryings after 2 minutes, carry out ultraviolet ray irradiation (irradiation distance is that 10cm, irradiation time are 30 seconds) with 1 120W/cm light harvesting type high-pressure mercury-vapor lamp, coated film is solidified.As previously discussed, make have thickness be 3.2 μ m, average roughness Ra=0.24 light diffusion layer relatively use anti-dazzle film.
Comparative example 4
Relative 100 parts of refractive index 1.51 (n as transparent resin
x) dipentaerythritol acrylate, add 3 parts of 2-hydroxy-2-methyl propiophenones, be 1.42 (n as 6 parts of refractive indexes of resin particle as light trigger
y), mean grain size is 3.0 μ m (D
y) silicone resin rounding spherical resin fine particles and 4 parts of refractive indexes be 1.49 (n
z), mean grain size is 2.5 μ m (D
z) the bowl-shape resin particle of acryl resin system, 130 parts of methyl isopropyl Ketones as solvent, disperseed 30 minutes with sand mill, obtain coating.Using reverse coating method that the coating that obtains is coated on by thickness is that 80 μ m, transmissivity are on the transparent base that constitutes of 94% TAC, 100 ℃ of dryings after 2 minutes, carry out ultraviolet ray irradiation (irradiation distance is that 10cm, irradiation time are 30 seconds) with 1 120W/cm light harvesting type high-pressure mercury-vapor lamp, coated film is solidified.As previously discussed, make have thickness be 3.2 μ m, average roughness Ra=0.18 light diffusion layer relatively use anti-dazzle film.
Then, carry out the evaluation of the foregoing description and comparative example by following method.
Visual valuation
At the liquid crystal display monitor central monitoring system of the commercially available high meticulous type that does not have anti-dazzle film (ア イ オ デ one machine: LCD-A15UR, picture dimension: 15 inches, resolution: UXGA, pel spacing: 133PPI), replace pasting comprehensive Polarizer, paste the anti-dazzle film of embodiment and comparative example on its surface.At first under the state of display image not, observe mirroring and white portion of exterior light, then show rest image, observe image blurring, glitter and viewing angle characteristic.
About anti-dazzle property, fluorescent light is mirrored from the front, observe the situation that its profile is mirrored.
About white portion, do not mirror fluorescent light, from top view, thus the blackness situation of observing anti-dazzle film.
About image blurring, use the software (Microsoft Windows (registered trademark)) of Microsoft, show the numeral of 11 of MS Ming Dynasty bodies, font size, can see fuzzy to observe digital demonstration from the distance of picture 50cm.
Glitter about image, glitter can see from the distance observation of picture 50cm.
About viewing angle characteristic, the degree that the contrast when observing the photochrome image of seeing regulation from the front reduces when 45 ° of angle tilts of watching.
Its evaluation result is shown in Table 1.Metewand in the table 1 is as follows.
About anti-dazzle property, A: do not see and mirroring, C: see and mirroring.
About white portion, A: do not see white portion, B: see white portion a little, but practical no problem, C: be clear that white portion.
About image blurring, A: do not see fuzzy, in bright gay color, C: see fuzzy.
About glittering A: do not see and glittering, B: see a little and glittering, but practical no problem, C: be clear that and glitter.
About viewing angle characteristic, A: almost can't see contrast and reduce C: be clear that contrast reduces.
Table 1
Anti-dazzle property | White portion | Image blurring | Glitter | Viewing angle characteristic | |
Embodiment 1 | A | A | A | A | A |
Embodiment 2 | A | B | A | A | A |
Embodiment 3 | A | A | A | B | A |
Comparative example 1 | A | A | A | C | C |
Comparative example 2 | C | A | A | C | C |
Comparative example 3 | A | C | C | A | A |
Comparative example 4 | A | C | C | C | A |
Can know from table 1, the relation of the refractive index of transparent resin and bowl-shape resin particle satisfies embodiment 1, the embodiment 2 of the relation of above-mentioned formula (1) and the anti-dazzle film of the present invention of embodiment 3, for white portion, image blurring, glitter and viewing angle characteristic, demonstrate good result, in contrast, the anti-dazzle film of comparative example 1 can not suppress to glitter, and viewing angle characteristic is also poor.For the anti-dazzle film of comparative example 2, anti-dazzle property, glitter, each characteristic of viewing angle characteristic is poor, the anti-dazzle film of comparative example 4 can not suppress white portion, image blurring, glitter.In addition, only use the anti-dazzle film of the comparative example 3 of spherical shape resin particle can not suppress white portion and image blurring.
Claims (9)
1. anti-dazzle film, have resin particle be dispersed in transparent resin mutually in and the light diffusion layer that constitutes, it is characterized in that described resin particle constitutes the refractive index n of transparent resin phase by the bowl-shape resin particle that the central portion of spherical shape resin particle and particle caves in into concavity at least
xRefractive index n with bowl-shape resin particle
zSatisfy the relation of following formula (1).
n
x-n
z≥0.03 (1)
2. anti-dazzle film according to claim 1 is characterized in that, the refractive index n of described spherical shape resin particle
yRefractive index n with described bowl-shape resin particle
zSatisfy the relation of following formula (2).
n
z<n
y (2)
3. anti-dazzle film according to claim 1 is characterized in that, the mean grain size D of described spherical shape resin particle
yBe 0.3 μ m~7.0 μ m, the mean grain size D of described bowl-shape resin particle
zBe 0.3 μ m~7.0 μ m.
4. according to claim 1 or 3 described anti-dazzle films, it is characterized in that the mean grain size D of described spherical shape resin particle
yMean grain size D with described bowl-shape resin particle
zSatisfy the relation of following formula (3).
0.7D
z≤D
y≤1.4D
z (3)
5. anti-dazzle film according to claim 1 is characterized in that, light diffusion layer is arranged on the one side at least of transparent base.
6. anti-dazzle film according to claim 1 is characterized in that light diffusion layer has convex-concave surface, and this convex-concave surface only forms by the spherical shape resin particle or by spherical shape particulate and bowl-shape resin particle.
7. anti-dazzle film according to claim 6 is characterized in that, the thickness of the thinnest portion of described light diffusion layer is thicker than the average height of described bowl-shape resin particle.
8. anti-dazzle film according to claim 6 is characterized in that, the mean grain size of described spherical shape resin particle be described bowl-shape resin particle average height 110~300%.
9. anti-dazzle film according to claim 6 is characterized in that, the average roughness Ra of described convex-concave surface is 0.1~1.0 μ m.
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TW200930755A (en) * | 2007-10-18 | 2009-07-16 | Sumitomo Seika Chemicals | Light diffusing agent |
CN101975973B (en) * | 2010-09-16 | 2013-12-11 | 宁波激智科技股份有限公司 | Optical reflective film, preparation method thereof and liquid crystal display device using same |
CN102043174B (en) * | 2010-11-05 | 2013-05-29 | 宁波激智新材料科技有限公司 | Microlens array film, preparation method thereof and LCD (Liquid Crystal Display) device |
TWI447923B (en) * | 2011-04-01 | 2014-08-01 | Eternal Chemical Co Ltd | Transmittance enhancement film and the solar cell module comprising the same |
CN102759761B (en) * | 2012-07-17 | 2014-10-08 | 宁波激智科技股份有限公司 | Optical thin film with high covering power and high luminance and display device comprising optical thin film |
JP6924202B2 (en) * | 2016-11-01 | 2021-08-25 | アルプスアルパイン株式会社 | Optical panel and its manufacturing method, equipment and transfer body and its manufacturing method |
Citations (5)
Publication number | Priority date | Publication date | Assignee | Title |
---|---|---|---|---|
JP2000039506A (en) * | 1998-07-21 | 2000-02-08 | Sekisui Plastics Co Ltd | Light diffusion sheet |
EP1266908A1 (en) * | 2000-03-21 | 2002-12-18 | Sekisui Plastics Co., Ltd. | Resin particle and process for producing the same |
JP2003004915A (en) * | 2001-04-17 | 2003-01-08 | Sekisui Plastics Co Ltd | Coating composition, coating material, optical diffusion sheet and liquid crystal display |
JP2003090906A (en) * | 2001-09-18 | 2003-03-28 | Daicel Chem Ind Ltd | Anisotropic diffusing film and device using the same |
CN2588389Y (en) * | 2002-12-13 | 2003-11-26 | 薛合源 | Light diffusion device |
-
2005
- 2005-03-16 CN CNB2005800003193A patent/CN100353187C/en not_active Expired - Fee Related
Patent Citations (5)
Publication number | Priority date | Publication date | Assignee | Title |
---|---|---|---|---|
JP2000039506A (en) * | 1998-07-21 | 2000-02-08 | Sekisui Plastics Co Ltd | Light diffusion sheet |
EP1266908A1 (en) * | 2000-03-21 | 2002-12-18 | Sekisui Plastics Co., Ltd. | Resin particle and process for producing the same |
JP2003004915A (en) * | 2001-04-17 | 2003-01-08 | Sekisui Plastics Co Ltd | Coating composition, coating material, optical diffusion sheet and liquid crystal display |
JP2003090906A (en) * | 2001-09-18 | 2003-03-28 | Daicel Chem Ind Ltd | Anisotropic diffusing film and device using the same |
CN2588389Y (en) * | 2002-12-13 | 2003-11-26 | 薛合源 | Light diffusion device |
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