JP2014085528A - White reflection film - Google Patents

Abstract

PROBLEM TO BE SOLVED: To provide a white reflection film capable of sufficiently suppressing sticking with a light guide plate in an ordinary state and suppressing sticking with the light guide plate even under wet heat environment regardless of a water-based coating layer.SOLUTION: The white reflection film has a water-based coating layer consisting of a binder resin and containing particles on the surface of a reflection film. On the surface of the coating layer, a coverage by the particles is 0.2-50%, and an average exposure rate of the particles is 2-97%. The binder resin contains a crosslinking group containing acrylic modified polyester resin of 30 mass% or more on the basis of mass of the binder resin. The amount of a crosslinking group in the crosslinking group containing acrylic modified polyester resin is 60 mol% or more and 200 mol% or less on the basis of 100 mol% of a polyester component in the crosslinking group containing acrylic modified polyester resin.

Description

  The present invention relates to a white reflective film. In particular, it is related with the white reflective film used for a liquid crystal display device.

  A backlight unit of a liquid crystal display device (LCD) includes a direct type having a light source on the back of the liquid crystal display panel and a reflective film on the back, and a light guide plate having a reflector on the back of the liquid crystal display panel. There is an edge light type provided with a light source on the side surface of the light guide plate. Conventionally, as a backlight unit used for a large LCD, a direct type (mainly a direct type CCFL) is mainly used from the viewpoint of excellent screen brightness and uniformity of brightness within the screen, and an edge is used. The light type was often used for relatively small LCDs such as notebook PCs. However, due to the recent development of light sources and light guide plates, the brightness and uniformity of brightness within the screen have been improved even for edge-light type backlight units. As a result, edge-light type backlight units have been used not only for relatively small size but also for large LCDs. This also has the advantage that the LCD can be made thinner.

  In the edge light type backlight unit, the light guide plate and the reflective film are in direct contact with each other. Therefore, in such a structure, when the light guide plate and the reflective film are attached, there is a problem in that the luminance of the attached portion becomes abnormal and in-plane variation in luminance occurs. Therefore, it is necessary to have a gap between the light guide plate and the reflective film and keep this gap constant. For example, by having particles on the surface of the reflective film, the gap between the light guide plate and the reflective film can be kept constant, and sticking of these can be prevented.

JP 2003-92018 A Special table 2008-512719 gazette JP 2009-244509 A

  As a conventional technique, an organic solvent-based coating liquid is used in a method of applying particles to the surface of a reflective film by coating. On the other hand, it is not preferable to use an organic solvent from an environmental point of view. Therefore, it is desired to impart particles to the surface of the reflective film using an aqueous coating liquid. However, when a water-based coating liquid is used, a binder resin is generally used for particle retention. However, in a conventional mode, for example, when used in a state where it is overlapped with a light guide plate, a durability test process for a liquid crystal television is performed. In an endurance test where temperature and humidity are applied over time, the coating layer is melted, thereby causing a problem that the light guide plate and the reflective film are adhered.

  Therefore, the present invention can sufficiently suppress sticking to the light guide plate in a normal state and white that can suppress sticking to the light guide plate even in a wet heat environment while being an aqueous coating layer. An object is to provide a reflective film.

The present invention adopts the following configuration in order to achieve the above-described problems.
1. A white reflective film having a water-based coating layer containing particles on the surface of the reflective film, which is made of a binder resin,
The coverage by the particles on the coating layer surface is 0.2 to 50%, the average exposure rate of the particles is 2 to 97%,
The binder resin contains 30% by mass or more of a crosslinkable group-containing acrylic modified polyester resin based on the mass of the binder resin, and the amount of the crosslinkable group in the crosslinkable group-containing acrylic modified polyester resin is the crosslinkable group-containing acrylic modified polyester resin. Is based on 100 mol% of the polyester component in 60 mol% or more and 200 mol% or less.
White reflective film.
2. 2. The white reflective film as described in 1 above, wherein the content of the particles in the coating layer is 5 to 50% by mass with respect to 100% by mass of the coating layer.
3. 3. The white reflective film as described in 1 or 2 above, wherein the average particle diameter (d) of the particles in the coating layer and the thickness (t) of the coating layer satisfy the following formula (1).
1 ≦ d (μm) / t (μm) ≦ 100 (1)
4). The white reflective film according to any one of 1 to 3 above, wherein the volatile organic solvent amount is 10 ppm or less.
5. The white reflective film of any one of said 1-4 used as a reflecting plate for surface light sources provided with a light-guide plate.

  According to the present invention, it is possible to sufficiently suppress sticking to the light guide plate in a normal state, and it is possible to suppress sticking to the light guide plate even in a wet heat environment while being an aqueous coating layer. A white reflective film can be provided.

It is a schematic diagram which shows an example of the cross section of the reflective film of this invention. It is a schematic diagram which shows the structure used for sticking evaluation in this invention. It is a schematic diagram which shows the method of the damage evaluation of the light-guide plate in this invention, and the drop-off evaluation of particle | grains.

The white reflective film of the present invention has a coating layer on the surface of the reflective film.
Hereafter, each structural component which comprises this invention is demonstrated in detail.

[Reflective film]
The reflective film in the present invention is a film made of a thermoplastic resin and having a white colorant or a void-forming agent contained in the film so as to exhibit a white color. As the colorant or void forming agent, for example, inorganic particles, organic particles, and a resin that is incompatible with the thermoplastic resin constituting the film (hereinafter, sometimes referred to as incompatible resin) are used. Can do.

  The reflectance at a wavelength of 550 nm of the reflective film is preferably 95% or more, more preferably 96% or more, and particularly preferably 97% or more. The reflective film may be a single layer film or a laminated film. Laminated film composed of a layer containing a relatively large amount of voids (reflective layer) and a layer containing a relatively small amount of voids or a layer containing no voids (support layer) from the viewpoint of obtaining high reflectivity and mechanical strength Is preferred. Moreover, as a thermoplastic resin which comprises a film, polyester, polyolefin, a polystyrene, and an acryl can be mentioned, for example, Polyester is preferable from a viewpoint of obtaining the white film excellent in a mechanical characteristic and thermal stability.

(polyester)
When using polyester as a thermoplastic resin of a reflective film, it is preferable to use polyester which consists of a dicarboxylic acid component and a diol component as polyester. Examples of the dicarboxylic acid component include terephthalic acid, isophthalic acid, 2,6-naphthalenedicarboxylic acid, 4,4′-diphenyldicarboxylic acid, adipic acid, and sebacic acid. Examples of the diol component include ethylene glycol, 1,4-butanediol, 1,4-cyclohexanedimethanol, and 1,6-hexanediol.

  Among these polyesters, aromatic polyesters are preferable, and polyethylene terephthalate is particularly preferable. Polyethylene terephthalate may be a homopolymer, but a copolymer is preferred. In particular, when a laminated reflective film composed of a layer containing a relatively large amount of voids and a layer containing a relatively small amount of voids or no voids is used as the reflective film, a layer containing a relatively large amount of voids The polyester used for (reflective layer) is preferably a copolymer. In this case, the ratio of the copolymerization component is, for example, 3 to 20 mol%, preferably 4 to 15 mol%, more preferably 5 to 13 mol%, based on 100 mol% of all dicarboxylic acid components. By setting the proportion of the copolymer component within this range, excellent film forming properties can be obtained even for a layer containing a relatively large amount of voids. Moreover, the reflective film excellent in thermal dimensional stability can be obtained.

(Coloring agent, void forming agent)
When inorganic particles are used as the colorant or void forming agent, the inorganic particles are preferably white inorganic particles. Examples of the white inorganic particles include barium sulfate, titanium dioxide, silicon dioxide, and calcium carbonate particles. The average particle diameter of the inorganic particles is, for example, 0.2 to 3.0 μm, preferably 0.3 to 2.5 μm, and more preferably 0.4 to 2.0 μm. Further, the content is preferably 25 to 55% by mass, more preferably 30 to 50% by mass based on the mass of the reflective film. By using such inorganic particles, it becomes easy to achieve a preferable reflectance. In addition, the film can be dispersed appropriately in the film, making it difficult for particles to aggregate and obtaining a film without coarse protrusions. At the same time, the surface of the film does not become too rough, and the gloss level is controlled within an appropriate range. can do. The inorganic particles may have any particle shape, for example, a plate shape or a spherical shape. The inorganic particles may be subjected to a surface treatment for improving dispersibility.

  When organic particles are used as the colorant or void forming agent, resin particles that are incompatible with polyester are used as the organic particles. As the organic particles, silicone resin particles, polystyrene resin particles, and polytetrafluoroethylene particles are preferable. The average particle diameter of the organic particles is, for example, 0.2 to 10 μm, preferably 0.3 to 8.0 μm, and more preferably 0.4 to 6.0 μm. Further, the content is preferably 25 to 55% by mass, more preferably 30 to 50% by mass based on the mass of the reflective film. By using such organic particles, it becomes easy to achieve a preferable reflectance. In addition, the film can be dispersed appropriately in the film, making it difficult for particles to aggregate and obtaining a film without coarse protrusions. At the same time, the surface of the film does not become too rough, and the gloss level is controlled within an appropriate range. can do. The organic particles may have any particle shape, for example, a plate shape or a spherical shape.

  Further, when an incompatible resin is used as the colorant or void forming agent, the incompatible resin is preferably polyolefin or polystyrene. Further, the content is preferably 25 to 55% by mass, more preferably 30 to 50% by mass based on the mass of the reflective film. By using such an incompatible resin, it becomes easy to achieve a preferable reflectance. In the case of an incompatible resin, if the content is too large, the bending moment of the reflective film tends to be too low.

[Coating layer]
The coating layer in this invention consists of binder resin, and contains particle | grains.
In the present invention, the coating layer is provided on the surface of the reflective film, but it may be provided on at least one surface on the light guide plate side, and may be provided on both surfaces of the reflective film.

(particle)
The particles in the coating layer may be organic particles, inorganic particles, or organic-inorganic composite particles.
Examples of the organic particles include polyester resin particles, acrylic-modified polyester resin particles, nylon resin particles, polypropylene resin particles, polystyrene resin particles, silicone resin particles, acrylic resin particles, styrene-acrylic resin particles, polyurethane resin particles, and divinylbenzene-acrylic. Examples thereof include polymer resin particles such as resin particles, polyimide resin particles, and melamine resin particles. Among these, polyester resin particles, acrylic-modified polyester resin particles, silicone resin particles, acrylic resin particles, and nylon resin particles are particularly preferable from the viewpoint that it is easy to form protrusions having an appropriate hardness for securing a gap.

Examples of the inorganic particles include (1) silicon dioxide (including hydrate, silica sand, quartz, etc.); (2) alumina in various crystal forms; (3) silicic acid containing 30% by mass or more of SiO ₂ component. Salts (eg, amorphous or crystalline clay minerals, aluminosilicates (including calcined products and hydrates), warm asbestos, zircon, fly ash, etc.); (4) oxides of Mg, Zn, Zr and Ti; (5) Sulfates of Ca and Ba; (6) Phosphates of Li, Ba and Ca (including monohydrogen and dihydrogen salts); (7) Benzoates of Li, Na and K; (8) Terephthalate of Ca, Ba, Zn and Mn; (9) titanate of Mg, Ca, Ba, Zn, Cd, Pb, Sr, Mn, Fe, Co and Ni; (10) chromic acid of Ba and Pb Salt; (11) carbon (eg carbon black, (Graphite, etc.); (12) glass (for example, glass powder, glass particles, etc.); (13) carbonates of Ca and Mg; (14) fluorite; (15) spinel oxide. Among these, silica particles are preferable, and aggregated silica particles are particularly preferable from the viewpoint that it is easy to form protrusions having an appropriate hardness for securing a gap.

  Further, as the particles in the present invention, organic-inorganic composite particles such as inorganic particles coated with an organic substance and organic particles coated with an inorganic substance can also be used. Specifically, the organic-inorganic composite particles include, for example, an organic-inorganic hybrid in which a polymer having an organometallic compound group such as a silylalkyl group at the side chain or terminal and an inorganic compound component such as silica are complexed by a covalent bond. Particles made of materials, particles whose surface is bonded with inorganic polymer particles such as crosslinked polystyrene on the surface of inorganic particles, or particles where inorganic particles such as alumina are fixedly coated on the surface of organic polymer particles, etc. Is mentioned.

  The average particle size of the particles in the coating layer is preferably 2 μm or more and 100 μm or less from the viewpoint that the distance between the light guide plate and the film is kept constant and it is easy to prevent them from sticking. If the average particle size is too small, the white reflective film tends to be partially adhered to the light guide plate. From such a viewpoint, the average particle diameter is more preferably 5 μm or more, further preferably 10 μm or more, particularly preferably 15 μm or more, and most preferably 20 μm. On the other hand, if it is too large, the particles tend to drop off, and if the drop occurs, it becomes a white spot defect in the backlight unit. From such a viewpoint, the average particle diameter is more preferably 90 μm or less, further preferably 80 μm or less, particularly preferably 70 μm or less, and most preferably 60 μm or less.

Further, particles in the present invention preferably has a S10 strength of ^{5.8~23.6N / mm 2 (0.6~2.4kgf / mm} 2). When S10 intensity | strength exists in the said numerical range, the suppression effect of the damage to a light-guide plate can be heightened, and drop-off | omission of particle | grains can be suppressed simultaneously. Moreover, the improvement effect of sticking suppression with a light-guide plate can be heightened. If the S10 strength is too low, the particles tend to fall off. Moreover, it exists in the tendency for sticking to a light-guide plate to produce easily. On the other hand, if it is too high, there is a high possibility that the light guide plate will be scraped and scratched when it comes into contact with the light guide plate. From such a viewpoint, the S10 strength is more preferably 7.8 to 19.6 N / mm ² (0.8 to 2.0 kgf / mm ² ), and more preferably 8.8 to 17.7 N / mm ² ( 0.9 to 1.8 kgf / mm ² ). The S10 strength of the particles can be achieved by adjusting the degree of polymerization, degree of crosslinking, and degree of crystallization of the particles. For example, in the same type of particles, when the degree of polymerization, the degree of crosslinking and the degree of crystallization are increased, the S10 strength tends to increase. From the above viewpoint, the particles in the present invention are preferably organic particles.

(Binder resin)
The binder resin in the coating layer contains a crosslinking group-containing acrylic modified polyester resin, which will be described later, in an amount of 30% by mass or more based on the mass of the binder resin. By setting it as such an aspect, sticking with a light-guide plate can be suppressed also in a humid heat environment. If the content is too small, sticking in such a humid heat environment cannot be suppressed. Therefore, it is more preferably 40% by mass or more, and further preferably 45% by mass or more. From this viewpoint, the upper limit is not particularly limited and is 100% by mass. On the other hand, if the amount is too large, the recoverability tends to be low. From this viewpoint, the content is preferably 70% by mass or less, more preferably 55% by mass or less.

(Crosslinking group-containing acrylic modified polyester resin)
The crosslinkable group-containing acrylic modified polyester resin in the present invention is a polyester (co) polymer whose main chain is modified with an acrylic (co) polymer. For example, the branch component is acrylic (co). A graft copolymer in which the main component is a polyester-based (co) polymer. Here, “(co) polymer” means a homopolymer or a copolymer. As the acrylic-modified polyester resin, for example, acrylic-modified polyester resins described in JP-A-63-37937, JP-A-11-198327 and the like can be used.

  The crosslinking group is not particularly limited as long as the acrylic-modified polyester can form a crosslinked structure. For example, an isocyanate group, a glycidyl group, and an oxazoline group can be preferably exemplified. These crosslinking groups are preferable from the viewpoint of moisture and heat blocking resistance. Although the aspect in which an acrylic modified polyester has a crosslinking group is not particularly limited, an aspect in which the acrylic (co) polymer constituting the branch component has a crosslinking group is preferable. By setting it as such an aspect, it becomes possible to form a crosslinked structure more efficiently than having a crosslinking group in a trunk component.

  The amount of the crosslinking group in the acrylic modified polyester resin is 60 mol% or more and 200 mol% or less, with the polyester component in the acrylic modified polyester resin being 100 mol%. Thereby, the heat-and-moisture resistance of an application layer can be improved and sticking with the light-guide plate in a wet heat environment can be suppressed. If there are too few cross-linking groups, the moisture-resistant heat blocking property of the white reflective film becomes poor, while if there are too many cross-linking groups, there is too much acrylic component in the coating layer, so the recoverability tends to deteriorate, The coating layer tends to be too hard, and the strength of the coating layer itself tends to decrease. From this viewpoint, the amount of the crosslinking group is more preferably 66 mol% or more, further preferably 70 mol% or more, and particularly preferably 80 mol% or more. Further, it is more preferably 165 mol% or less, further preferably 150 mol% or less, particularly preferably 135 mol% or less, and most preferably 120 mol% or less.

(Thermoplastic resin)
In addition to the crosslinking group-containing acrylic modified polyester resin, the binder resin of the coating layer preferably contains 30 to 70% by mass of a thermoplastic resin based on the mass of the binder resin. More preferably, it is 45-65 mass%. By containing the thermoplastic resin in such a content range, the adhesiveness of the coating layer to the reflective film and the recoverability of the film having the coating layer are excellent while maintaining the moisture and heat blocking resistance. When the content of the thermoplastic resin is 30% by mass or less, the adhesion of the coating layer to the reflective film tends to deteriorate, and it is obtained when the film having the coating layer is recovered and used as a recovered raw material. The film tends to turn yellow. On the other hand, when the amount of the thermoplastic resin is 70% by mass or more, the effect of suppressing sticking in a moist heat environment tends to be small.
Examples of the thermoplastic resin that can be added to the binder resin include polyester resin, acrylic resin, and urethane. Among these, a polyester resin is preferable from the viewpoint of good adhesion between the coating layer and the reflective film.

(Other ingredients)
The coating layer may contain components other than the above-described constituent components as long as the object of the present invention is not impaired. Examples of such components include ultraviolet absorbers, antistatic agents, fluorescent brighteners, waxes, particles different from the above particles, resins that can react with the acrylic modified polyester resin, and the like.

[Aspect of coating layer]
(Coverage)
The white reflective film of the present invention has a coating layer containing a crosslinkable group-containing acrylic-modified polyester resin and particles on the surface of the reflective film, and the coating layer further comprises a film made of a binder resin (hereinafter referred to as a binder resin film). In some cases, the particles are present in the particles), and the particles are coated on the surface of the white reflective film. The coverage with these particles is 0.2 to 50%, preferably 0.4 to 45%, more preferably 0.5 to 42%, particularly preferably 0.6 to 40%, as defined later. Means that the surface of the white reflective film is coated. When the coverage is in such a range, the effect of the coating layer can be achieved without significantly reducing the reflectance and luminance. If the coverage is less than 0.2%, it becomes impossible to maintain a gap between the light guide plate and the film, and there is a possibility that luminance unevenness occurs due to contact and sticking between the light guide plate and the film. Further, the friction between the light guide plate and the film tends to increase, and the light guide plate is easily scratched. On the other hand, when the coverage is 50% or more, the presence of too many particles on the surface of the film may reduce the reflectivity, which may reduce the brightness of the display device. The coverage can be adjusted by adjusting the average particle size and content of the particles in the coating layer. If the average particle size is increased or the content is increased, the coverage tends to increase.

In the present invention, the coverage ratio is obtained by observing a cross section of a measurement area having a total length of 6 mm in each measurement area having a length of 3 mm in two orthogonal directions within the film plane, and the white film surface is covered with particles in the measurement area Is defined as a percentage.
Specifically, using a microtome, the section sample 1 is cut out so that the plane formed by one direction randomly selected in the film plane and the thickness direction of the film is a cut plane. The section sample 2 is cut out so that the surface formed by the direction perpendicular to the one direction randomly selected in 1 and the thickness direction is a cut surface, and the area of the coated layer surface 3 mm in length in the section of the section sample 1; In the cross section of the slice sample 2, the measurement area of 6 mm in total with the 3 mm long area of the coating layer surface was observed at a magnification of 3000 times using a Hitachi S-4700 field emission scanning electron microscope. In the measurement region in the cut surface of the sample, the lengths of the portions of the film surface not covered with particles (reference numeral 201 in FIG. 1) are integrated and obtained by the following formula (see FIG. 1). .
Coverage rate = (6 mm− (integrated length of the portion not covered with particles (mm))) / 6 mm
× 100 (%)

  In addition, when the maximum diameter part of the particle is outside the surface of the binder resin film in the coating layer (reference numeral 203 in FIG. 1) on the cut surface, the part covered with the maximum particle diameter is covered with the particle. If the maximum diameter portion of the particle is inside the binder resin film surface, that is, if it is sinking in the binder resin film, the binder resin film of the particles It is considered that the maximum diameter of the dome-shaped protrusion formed by the portion outside the surface is covered with the particles (for example, reference numeral 102 in FIG. 1). At this time, it is considered that particles satisfying the exposure rate described later are covered, and even if there are particles that do not satisfy the exposure rate, they are not covered (for example, reference numerals 101 and 104 in FIG. 1). ).

(Exposure rate)
In the calculation of the coverage in the present invention, the particles treated as covering the surface of the white reflective film are those in which part or all of the particles are exposed on the surface of the white reflective film. This exposure refers to exposure at an exposure rate of 1% or more as defined by the present invention. Thus, particles with an exposure rate of less than 1% are not treated as coated particles.

  The particles are supported by a binder resin film provided on the surface of the reflective film in order to support the particles on the surface of the reflective film. For this reason, some of the particles are in contact with the film or sink. The exposure rate of 100% corresponds to the situation where the surface of the coating is in contact with the surface of the particle on the cut surface and the surface of the white reflective film is supported by the coating. The exposure rate of 0% is reflected on the cut surface. The particles are completely submerged in the film provided on the film surface, and the exposure rate of 50% is such that half of the particles are embedded in the film provided on the reflective film surface at the cut surface. The other half is in a state of protruding out of the film.

To define the exposure rate more precisely, the exposure rate is calculated by drawing a straight line passing through the center of the cross section of the particle in the cut surface of the slice sample and perpendicular to the surface of the binder resin film. Of the two points that intersect the particle surface, S is the point on the exposed surface, T is the point on the unexposed surface, and the point where the straight line intersects the binder resin coating surface. When B, it is expressed by (distance between S and B) / (distance between S and T) (see FIG. 1).
That is, the exposure rate (%) is defined by the following formula.
Exposure rate = (distance between S and B) / (distance between S and T) × 100 (%)
The center of the cross section of the particle in the cut surface is the center of the circle of the cross section when the particle is spherical, and the center of gravity of the cross section when the particle is non-spherical.

  In the present invention, similarly to the above-described coverage, when the measurement area is 3 mm in length in each of the two orthogonal directions in the film plane and the measurement area has a total length of 6 mm, the exposure rate of each particle in the measurement area The average value (average exposure rate, when calculating the average value, those with an exposure rate of 0% or less are not included) is 2 to 97%. When in this range, a gap with the light guide plate can be ensured, and at the same time, dropout of particles can be suppressed. When the average exposure rate is too low, it is difficult to secure a gap, while when it is too high, it is difficult to suppress particle dropout.

(Thickness of coating layer)
The thickness of the coating layer may be adjusted so that the coverage and the average exposure rate specified by the present invention are obtained in consideration of the amount of particles used and the particle size. For example, if the coating layer is too thick, the particles tend to be buried, and the coverage and average exposure rate tend to be low.
From such a viewpoint, it is preferable that the relationship between the thickness (t) of the coating layer and the average particle diameter (d) of the particles satisfies the following formula (1).
1 ≦ d (μm) / t (μm) ≦ 100 (1)

By setting it as such an aspect, it will become easy to satisfy the coverage and exposure rate which this invention prescribes | regulates. From this viewpoint, in the above formula, the left side is preferably 5 or more, and more preferably 10 or more. Further, the right side is preferably 80 or less, more preferably 70 or less.
The specific range of the thickness of the coating layer is preferably 0.3 to 10 μm, more preferably 0.5 to 5 μm.

[Method for producing white reflective film]
Hereinafter, an example of the method for producing the white reflective film of the present invention will be described. In this example, an embodiment of a laminated reflective film having a reflective layer and a support layer is employed as the reflective film.
First, a polyester composition for forming a reflective layer and a polyester composition for forming a support layer are prepared, sufficiently dried, and then charged into separate extruders and melt-extruded. The polyester composition is preferably filtered using a nonwoven fabric type filter having an average opening of 10 to 100 μm, preferably an average opening of 20 to 50 μm, and made of stainless steel fine wires having a wire diameter of 15 μm or less. By performing this filtration, it is possible to suppress agglomeration of particles that are usually agglomerated and become coarse agglomerated particles, and to obtain a laminated film with few coarse foreign matters.
The filtered polyester composition is extruded in a multilayer state from a die by a simultaneous multilayer extrusion method using a feed block in a molten state to produce a laminated unstretched sheet.

  The laminated unstretched sheet extruded from the die is cooled and solidified by a casting drum to form a laminated unstretched film. This laminated unstretched film is heated by roll heating, infrared heating or the like, and stretched in the longitudinal direction to obtain a laminated longitudinally stretched film. This stretching is preferably performed by utilizing the difference in peripheral speed between two or more rolls. The stretching is preferably performed at a temperature equal to or higher than the glass transition point (Tg) of the polyester. The draw ratio in the machine direction (machine axis direction) is preferably 2.2 to 4.0 times, more preferably 2.3 to 3.9 times. If it is less than 2.2 times, the thickness unevenness of the film is deteriorated and a good film cannot be obtained, and if it exceeds 4.0 times, breakage tends to occur during film formation, which is not preferable.

  Subsequently, the laminated film after the longitudinal stretching is sequentially subjected to lateral stretching, heat setting, and thermal relaxation to form a laminated biaxially oriented film. These processes are performed while the film is running. The transverse stretching process starts from a temperature higher than Tg. Although the temperature rise in the transverse stretching process may be continuous or stepwise (sequential), the temperature is usually raised sequentially. For example, the transverse stretching zone of the tenter is divided into a plurality along the film running direction, and the temperature is raised by flowing a heating medium having a predetermined temperature for each zone. The stretching ratio in the transverse direction (direction perpendicular to the longitudinal direction) is preferably 2.5 to 4.5 times, more preferably 2.8 to 3.9 times, although it depends on the required characteristics of this application. If it is less than 2.5 times, the thickness unevenness of the film is deteriorated and a good film cannot be obtained, and if it exceeds 4.5 times, breakage tends to occur during film formation. Hereinafter, the melting point of polyester is abbreviated as Tm.

  The film after transverse stretching is heat-treated while being held at both ends (Tm-100 ° C.) to (Tm-20 ° C.) at a temperature (Tm is the melting point of the polyester) at a constant width or a width reduction of 10% or less. It is better to reduce the shrinkage rate. When the heat treatment temperature is higher than (Tm−20 ° C.), the flatness of the film is deteriorated and the thickness unevenness is increased, which is not preferable. If it is lower than (Tm-100) ° C., the heat shrinkage rate may increase, which is not preferable. Further, in order to adjust the heat shrinkage, both ends of the film being held can be cut off, the take-up speed in the film vertical direction can be adjusted, and the film can be relaxed in the vertical direction. As a means for relaxing, the speed of the roll group on the tenter exit side is adjusted. As the rate of relaxation, the speed of the roll group is reduced with respect to the film line speed of the tenter, preferably 0.1 to 2.5%, more preferably 0.2 to 2.3%, particularly preferably 0.3. The film is relaxed by performing a speed reduction of ˜2.0% (this value is referred to as “relaxation rate”), and the longitudinal heat shrinkage rate is adjusted by controlling the relaxation rate. Further, the width of the film in the horizontal direction can be reduced in the process until both ends are cut off, and a desired heat shrinkage rate can be obtained.

  As a coating liquid for forming a coating layer on the surface of the reflective film thus prepared, a binder resin, particles, surfactants described later as optional components and other components were dispersed or dissolved in water. The coating liquid is applied in a predetermined amount using a coating apparatus, and dried in an oven set at a temperature of 70 to 120 ° C., preferably stepwise to form a coating layer, whereby the white reflective film of the present invention is formed. Can be obtained.

  The coating layer may be formed by applying a coating liquid for forming the coating layer to the manufactured film (so-called off-line coating), or may be formed by applying to the film being manufactured. (So-called inline coating). In the case of applying to a film during production, the coating liquid is preferably applied to a uniaxially oriented film stretched in one direction, and stretched in the other direction as it is and fixed by heat. As a coating method, a roll coating method, a gravure coating method, a roll brush method, a spray method, an air knife coating method, an impregnation method, a curtain coating method, or the like can be used alone or in combination. Here, a gravure coating method is preferred in order to transfer the particles from the coater evenly to the film. Further, the solvent may be an aqueous coating solution and is preferably composed only of water. However, a solvent in which a small amount of an organic solvent soluble in water is mixed with water as long as the object of the present invention is not impaired is used. be able to. As solid content concentration of a coating liquid, 10-50 mass% is preferable. If the coating solution concentration exceeds 50%, it tends to be difficult to suppress the aggregation of particles in the coating solution. On the other hand, if the coating solution concentration is less than 10% by mass, the coating layer tends to be thinned, and the particles fall off. It tends to be difficult to suppress.

  A small amount of a surfactant can be added to the coating liquid for forming the coating layer for the purpose of improving the wettability with respect to the reflective film. Preferred surfactants include, for example, nonionic surfactants such as polyoxyethylene alkyl phenyl ether, polyoxyethylene alkyl ether, sorbitan fatty acid ester, fluoroalkyl carboxylates, perfluoroalkylbenzene sulfonates, perfluoro Fluorosurfactants such as alkyl quaternary ammonium salts and perfluoroalkyl polyoxyethylene ethanol can be mentioned. As surfactant, 1 mass%-20 mass% are preferable in solid content of a coating liquid. When it is 1% by mass or less, the wettability with respect to the film tends to be poor. When it is 20% by mass or more, other coating liquid performance tends to be difficult to achieve.

[Characteristics of reflective film]
(Reflectance)
The reflectance measured from the coating layer side of the white reflective film of the present invention is preferably 95% or more, more preferably 96% or more, and still more preferably 97% or more. When the reflectance is 95% or more, high luminance can be obtained when used in a liquid crystal display device or illumination. Such reflectivity tends to increase when the void content of the reflective film is increased, and the aspect of each layer is preferable, such as increasing the content of the void forming agent or increasing the thickness of the reflective layer in the reflective film. It can achieve by making it an aspect.

(Amount of volatile organic solvent)
In the white reflective film of the present invention, the coating layer is aqueous, and the amount of volatile organic solvent measured by the method described later is preferably 10 ppm or less. Thereby, for example, in an edge light liquid crystal display, the merit of improving the durability of the light guide plate in direct contact with the reflective film can be exemplified. From this viewpoint, it is more preferably 5 ppm or less, further preferably 3 ppm or less, and ideally 0 ppm. In the present invention, in order to reduce the amount of the volatile organic solvent, it is preferable to adopt the above-described method without adopting the solution coating method using a large amount of the organic solvent in forming the coating layer.

Hereinafter, the present invention will be described in detail by way of examples. Each characteristic value was measured by the following method.
(1) Light reflectance The integrating sphere was attached to a spectrophotometer (Shimadzu Corporation UV-3101PC), the reflectance when the BaSO ₄ white plate was 100% was measured at a wavelength of 550 nm, and this value was defined as the reflectance. In addition, what is necessary is just to implement a measurement in the surface used as the light-guide plate side. In this invention, it carried out on the surface of the side which has a coating layer.

(2) Average particle size of void forming agent (inorganic particles) The particle size distribution of the particles was obtained with a particle size distribution meter (LA-950, manufactured by Horiba, Ltd.), and the particle size at d50 was defined as the average particle size.

(3) Average particle diameter of particles in coating layer (d)
Using an S-4700 field emission scanning electron microscope manufactured by Hitachi, Ltd., 100 particles were arbitrarily measured at a magnification of 1000 times to obtain an average particle diameter. In addition, in the case of other than spherical shape, it was determined by (major axis + minor axis) / 2. Here, the minor axis is the maximum diameter orthogonal to the major axis.

(4) Particle exposure rate (4-1) Preparation of sample Using a microtome, section sample 1 and section sample 2 were cut out from an epoxy-embedded film. The section sample 1 is a section sample cut out so that the surface formed by one direction randomly selected in the film plane and the thickness direction of the film is a cut surface, and the section sample 2 is selected by the section sample 1 This is a slice sample cut out so that the surface formed by the direction perpendicular to one random direction and the thickness direction is a cut surface.

(4-2) Measurement Hitachi S-4700 type measurement area having a total length of 6 mm including a 3 mm long area of the coated layer surface of the slice sample 1 and a 3 mm long area of the coated layer surface of the slice sample 2 Observation was performed at a magnification of 3000 times using a field emission scanning electron microscope.
As for the exposure rate, when a straight line passing through the center of the cross section of the particle in the cut surface of the slice sample and perpendicular to the coating surface made of the binder resin is drawn, this straight line intersects the surface of the particle in the cut surface of the film slice. Of the two points, the point on the exposed side surface is S, the point on the unexposed surface is T, and the point where the previous straight line intersects the film surface made of the binder resin is B, It is expressed by (distance between S and B) / (distance between S and T) (see FIG. 1).
That is, the exposure rate (%) is defined by the following formula.
Exposure rate = (distance between S and B) / (distance between S and T) × 100 (%)
The center of the cross section of the particle in the cut surface was the center of the circle of the cross section when the particle was spherical, and the center of gravity of the cross section when the particle was non-spherical.
Moreover, this measurement was implemented about all the particles observed in the said measurement area | region of 6 mm, and made the average value the average exposure rate.

(5) Coverage ratio of film surface with particles (5-1) Preparation of sample The sample obtained in the above (4-1) was evaluated.
(5-2) Measurement About a measurement area having a total length of 6 mm including an area of 3 mm in the length of the coating film of the binder of the section sample 1 and an area of 3 mm in the length of the coating film of the binder in the section sample 2 Using a scanning electron microscope Schottky emission electron beam system S-4300SE / N, observation was performed at a magnification of 3000 times.
The coverage was obtained from the following formula by integrating the lengths of the film surface portions not covered with the particles in the measurement region in the cut surface of the section sample (see FIG. 1).
Coverage rate = (6 mm− (integrated length of the portion not covered with particles (mm))) / 6 mm
× 100 (%)

(6) Coating thickness A cross section in the thickness direction of a film sample was observed and photographed at a magnification of 3000 times using a Hitachi scanning electron microscope Schottky emission electron beam system S-4300SE / N. The thickness of the coating film was measured in (for example, reference numeral 204 in FIG. 1), and 10 points were arbitrarily measured to obtain an average value thereof.

(7) Adhesion spots evaluation (adhesion evaluation)
Take out the chassis from LG's LED liquid crystal television (LG42LE5310AKR) and place it on a horizontal desk so that the inside of the television is facing upward. On top of that, a white reflective film that is almost the same size as the chassis, with the coating layer facing upward In addition, a light guide plate and three optical sheets (two diffusion films and one prism) originally provided in the television were placed thereon. Next, an equilateral triangular base (reference numeral 601 in FIG. 2) having three circular legs with a diameter of 5 mm as shown in FIG. 2 is placed in the area including the most severe part of the unevenness of the chassis in the plane. An additional 20 kg weight (reference numeral 602 in FIG. 2) is placed on the top, and the region surrounded by the three legs is visually observed. If there is no abnormally bright part, “no adhesion spots” (adhesion spots evaluation) ○). If there is an abnormally bright part, place the DBEF sheet originally provided on the television on top of the three optical sheets and observe it in the same manner. When there was a spot (evaluation x), and when there was no abnormally bright part, it was set as "there was almost no adhesion spot" (evaluation (triangle | delta)). In addition, the area surrounded by the three legs was a substantially equilateral triangle having a side length of 10 cm.

(8) Evaluation of scratches on light guide plate (evaluation of shaving property) and evaluation of dropout of particles As shown in FIG. 3, an iron plate (length 200 mm × width 200 mm × thickness 3 mm) at the end of the handle portion (reference numeral 7 in FIG. 3) 3 and a weight of about 200 g) are firmly pasted, and a white reflective film (reference numeral 9 in FIG. 3) having a width of 250 mm × length of 200 mm with the evaluation surface facing upward is 25 mm from both ends in the width direction. Was pasted so that the part of the plate protruded from the iron plate (so that the central 200 mm × 200 mm portion overlapped the iron plate). At this time, the evaluation surface (coating layer surface) of the white reflective film was placed outside. In addition, the 25 mm portion remaining at both ends in the width direction of the white reflective film is folded back to the back side of the iron plate, and the end portion of the film (the portion where the blade is inserted with a knife or the like at the time of sampling) has the effect of scraping the light guide plate. Reduced as much as possible.
Next, a light guide plate with a dot surface up (with a size of at least 400 mm × 200 mm) is fixed on a horizontal desk, and the evaluation surface and the light guide plate contact the white reflective film fixed on the iron plate created above. As described above, the white reflective film side surface is placed on the light guide plate, and a 1 kg weight (reference numeral 10 in FIG. 3) is placed thereon, and the steel plate is at a distance of 200 mm (in the region of 400 mm × 200 mm). The reciprocating film was moved back and forth 15 times at a speed of about 5 to 10 seconds. Then, on the surface of the light guide plate, the degree of shaving and the presence or absence of particles dropped from the film were observed using a 20-fold magnifier and evaluated according to the following criteria.
In the entire range of 400 mm × 200 mm rubbed on the light guide plate, if there are no scratches that can be observed with a loupe after 15 reciprocating movements, it is determined that “cannot be scraped” (scraping evaluation ○), and scratches that can be observed after 10 reciprocating movements. Although there were no scratches that could be observed after 15 reciprocating movements, “scratch was difficult” (shave evaluation Δ), and when there were scratches that could be observed after 10 reciprocations, “scraped” (scraping evaluation ×).
Moreover, after 15 reciprocating movements, if there was no white foreign matter that could be observed with a loupe in the entire range of 400 mm × 200 mm rubbed on the light guide plate, it was determined that “particles did not fall off” (dropout evaluation ○). In addition, when there is a white foreign matter that can be observed, the white foreign matter is observed with a microscope to confirm that the white foreign matter is contained in the coating layer. “Almost no dropout” (dropout evaluation Δ), and if 6 or more, “particles dropout” (dropout evaluation ×).
In the evaluation, in order to suppress the influence of the dot size as much as possible, an area having a large dot size was selected as much as possible on the light guide plate, and the evaluation samples were aligned.
In the evaluation, the white reflective film was placed in an environment of at least a temperature of 23 ° C. and a relative humidity of 55 RH% for 3 days, and the evaluation was performed after the coating layer was sufficiently stabilized.

(9) Amount of Volatile Organic Solvent At room temperature (23 ° C.), 1 g of a film sample was placed in a 10 L fluororesin bag, and the inside was purged with pure nitrogen and sealed. Next, immediately from the nitrogen in the bag, 0.2 L and 1.0 L of nitrogen were collected in two analytical TENAX-TA collection tubes at a flow rate of 0.2 L / min. The mass of the organic solvent component contained in the collected nitrogen was quantified by HPLC, GCMS. The obtained value is converted into the amount in 10 L of nitrogen, and the mass of the organic solvent volatilized in 10 L of nitrogen is obtained from 1 g of the film sample, and the amount of volatile organic solvent (unit: ppm, based on the mass of the film sample) did. The aldehydes were quantified by HPLC by eluting the aldehyde derivatized product from the collection tube with acetonitrile. Moreover, when the value was different between HPLC and GCMS, the value of the more detected one was adopted.
Evaluation was made when the amount of the volatile organic solvent was 10 ppm or less.

(10) Humidity and heat blocking resistance evaluation Condition 1: The front and back of the sample film are overlapped and pressurized to 0.6 kg / cm ² and left in a well-known high-temperature and high-humidity tank set at 60 ° C. and 90% RH for 17 hours. . If the taken-out film was not attached or only slightly attached and could be easily peeled off, and the coating layer remained without melting, it was evaluated as “Good”. When the film was stuck and delamination occurred at the time of peeling or the coating layer was melted, it was rated as x.
Condition 2: The light guide plate is taken out from the backlight of the 32-inch Sony Bravia LED edge type television KDL-32EX700, cut to 5 cm × 10 cm, and overlapped so that the patterning surface of the light guide plate and the coating surface of the sample film are in contact with each other. Pressurize to 0.08 kg / cm ² and leave in a high temperature and high humidity tank set at 60 ° C. and 90% RH for 17 hours. If the taken-out film and the light guide plate were not attached or only slightly attached, they could be easily peeled off, and the coating layer remained without being melted. On the other hand, if the film and the light guide plate were adhered and delamination occurred during peeling or the coating layer was melted, the evaluation was x.
If both of the above conditions 1 and 2 are ○, the moisture and heat blocking resistance satisfies practical performance, and if either of the conditions 1 and 2 is ×, it can be evaluated that the moisture and heat blocking resistance does not satisfy the practical performance. .

(11) Love-off evaluation The surface of the coating layer was rubbed with a finger, and the state of the coating layer after rubbing was visually observed and evaluated according to the above criteria.
○: No change is observed on the surface of the coating layer.
Δ: The coating layer was slightly peeled off.
X: The coating layer was peeled off.

(12) Recoverability Weigh 20 g of the sample film, cut it into small pieces, put it in a flask, stir and melt at 300 ° C. for 15 minutes in a vacuum state, and then fill the flask with nitrogen and further in a nitrogen atmosphere, 300 Stir and melt at 15 ° C. for 15 minutes. The molten polymer is taken out, sandwiched between metal plates and pressed to create a plate. Observe the color of the resulting plate visually. If the level is low and recyclable, it will be rated as ◯. If it is yellow and difficult to recycle, it will be rated as △. If it was a serious level, it was set as x evaluation.

[Examples 1-9, Comparative Examples 3-7]
132 parts by mass of dimethyl terephthalate, 18 parts by mass of dimethyl isophthalate (12 mol% with respect to the acid component of the polyester), 96 parts by mass of ethylene glycol, 3.0 parts by mass of diethylene glycol, 0.05 parts by mass of manganese acetate, 0.012 parts by mass of lithium acetate was charged into a rectification column and a flask equipped with a distillation condenser, and heated to 150 to 235 ° C. with stirring to distill methanol to conduct a transesterification reaction. After methanol was distilled, 0.03 parts by mass of trimethyl phosphate and 0.04 parts by mass of germanium dioxide were added, and the reaction product was transferred to the reactor. Subsequently, while stirring, the pressure in the reactor was gradually reduced to 0.5 mmHg and the temperature was raised to 290 ° C. to carry out a polycondensation reaction. The amount of the diethylene glycol component relative to the acid component of the obtained copolyester was 2.5% by mass, the amount of germanium element was 50 ppm, and the amount of lithium element was 5 ppm. A masterbatch containing 48% by mass of barium sulfate having an average particle size of 1.0 μm as inorganic particles was prepared in the obtained copolymerized polyester, and this was used as a layer A polymer for forming a reflective layer (layer A). .

Further, using the masterbatch containing 48% by mass of barium sulfate described above and a copolyester before adding barium sulfate, the support layer (layer B) is diluted to 5% by mass of barium sulfate. Used as layer B polymer to form
Supply to two extruders each heated to 275 ° C., layer A polymer (barium sulfate concentration 48 mass%), layer B polymer (barium sulfate concentration 5 mass%), layer A and layer B are layer B The layers were joined using a three-layer feed block device so as to have a laminated structure of / layer A / layer B, and formed into a sheet shape from a die while maintaining the laminated state. Further, the unstretched film obtained by cooling and solidifying the sheet with a cooling drum having a surface temperature of 25 ° C. is heated at 83 ° C. to be 2 in the film forming machine axial direction (hereinafter sometimes referred to as the longitudinal direction or the longitudinal direction or MD). The film was stretched 8 times and cooled with a roll group at 25 ° C.
Subsequently, the coating liquid shown in Table 1 (water-based coating liquid with a solid content concentration of 30% by mass) was applied to one side of the film with a direct gravure coater so that the coating layer thickness after drying would be the thickness shown in Table 2. did.
Subsequently, the both ends of the film are guided to a tenter while being held by clips and are perpendicular to the longitudinal direction in an atmosphere heated to 115 ° C. (hereinafter sometimes referred to as a width direction or a transverse direction or TD). The film was stretched 3.7 times. Thereafter, heat setting was performed at 195 ° C. in a tenter and the mixture was cooled to room temperature to obtain a biaxially stretched film. This biaxially stretched film contains fine voids. The evaluation results of the obtained film are shown in Table 2.

[Comparative Example 1]
The same operation as in Example 1 was performed except that the coating layer was not applied. The evaluation results are shown in Table 2.

[Comparative Example 2]
After the uniaxial stretching, on the biaxially stretched film obtained in the same manner as in Example 1 except that the coating layer before biaxial stretching is not applied, the following recipe is prepared with a direct gravure coating device. A coating liquid having the composition shown was applied at a wet thickness of 15 g / m ² and then dried at 80 ° C. in an oven to obtain a film.

(Preparation recipe, solid content concentration 30% by mass)
-Particles: BM30X-55 manufactured by Sekisui Plastics Co., Ltd. (highly crosslinked acrylic particles, non-porous particles, powder, described as BM30X-55 in the table) ... 4.5 mass%
Acrylic resin (thermoplastic resin): DIC's ACRICID A-817BA (described as A-817BA in the table): 33% by mass
-Crosslinking agent: Coronate HL manufactured by Nippon Polyurethane Industry Co., Ltd. (Isocyanate-based crosslinking agent, solid content concentration 75% by mass, described as coronate in the table) ...
Diluting solvent: butyl acetate 50.5% by mass
The evaluation results of the obtained film are shown in Table 1. In addition, the solid content ratio of each component in the coating layer obtained from the above recipe is as follows.
・ Particles: 15% by mass
・ Acrylic resin (thermoplastic resin): 55% by mass
・ Crosslinking agent: 30% by mass

[Components of coating layer]
2003LS: Arkema (nylon 12, average particle size 50 μm, non-porous particles, powder)
SK-RP-25CL: Seishin company (polyethylene terephthalate, average particle size 25 μm, non-porous particles, powder)
GX-811: Mutual chemistry (water-soluble polyester, Tg 64 ° C., solid content concentration 30% by mass)
A-215GE: Takamatsu oil and fat (glycidyl group-containing acrylic modified polyester resin, Tg 40 ° C., solid content concentration 30% by mass)
A-645GH: Takamatsu oil and fat (glycidyl group-containing acrylic modified polyester resin, Tg 55 ° C., solid content concentration 30% by mass)
A-647GEX: Takamatsu oil and fat (glycidyl group-containing acrylic modified polyester resin, Tg 60 ° C., solid content concentration 20% by mass)
A-645GE: Takamatsu oil and fat (glycidyl group-containing acrylic modified polyester resin, Tg 55 ° C., solid content concentration 30% by mass)
Surfactant: Emulgen 420 (ether-based nonionic surfactant) manufactured by Kao Corporation

  Even if the white reflective film of the present invention is a water-based coating layer obtained from a water-based coating solution, the coating layer does not melt in a moist heat environment, has good moisture and heat blocking resistance, and is sufficiently attached to the light guide plate. Can be suppressed. Therefore, for example, it can be suitably used as a reflective film for a surface light source including a light guide plate, particularly as a reflective film used in an edge light type backlight unit as used in a liquid crystal display device or the like.

101 to 105 Particles 2 Binder resin film 201 Part not covered with particles 202 Part covered with particles 203 Binder resin film surface 204 Coating layer thickness 3 Reflective film 4 Chassis 5 White reflective film, light guide plate, optical sheet lamination Object 601 Equilateral triangle base 602 Weight 7 Handle part 8 Iron plate 9 White reflective film 10 Weight 11 Light guide plate 1101 dots

Claims (5)

A white reflective film having a water-based coating layer containing particles on the surface of the reflective film, which is made of a binder resin,
The coverage by the particles on the coating layer surface is 0.2 to 50%, the average exposure rate of the particles is 2 to 97%,
The binder resin contains 30% by mass or more of the crosslinkable group-containing acrylic modified polyester resin based on the mass of the binder resin, and the amount of the crosslinkable group in the crosslinkable group-containing acrylic modified polyester resin is the crosslinkable group-containing acrylic modified polyester resin. Is based on 100 mol% of the polyester component in 60 mol% or more and 200 mol% or less.
White reflective film.   The white reflective film of Claim 1 whose content of the particle | grains in an application layer is 5-50 mass% with respect to 100 mass% of mass of an application layer. The white reflective film of Claim 1 or 2 with which the average particle diameter (d) of the particle | grains in a coating layer and the thickness (t) of a coating layer satisfy | fill following formula (1).
1 ≦ d (μm) / t (μm) ≦ 100 (1)   The white reflective film of any one of Claims 1-3 whose amount of volatile organic solvents is 10 ppm or less.   The white reflective film of any one of Claims 1-4 used as a reflecting plate for surface light sources provided with a light-guide plate.