SWITCHING LENS FOR DISPLAY APPARATUS AND METHOD FOR MANUFACTURING THE SAME

Disclosed are a switching lens and a method for manufacturing the same. The switching lens having liquid crystals of highly uniform orientation can be obtained by minimizing the thickness deviation of an alignment film formed on the whole curvature surface of a lenticular pattern. The switching lens of the present invention comprises a resin layer having a lenticular pattern and an alignment film on the resin layer. The alignment film covers the whole curvature surface of the lenticular pattern and has the maximum thickness equal to or less than 0.01 times the maximum radius of curvature of the lenticular pattern.

TECHNICAL FIELD

The present invention relates to a switching lens for a display apparatus and a method for manufacturing the same, and more particularly, to a switching lens having liquid crystals of highly uniform orientation which can be obtained by minimizing the thickness deviation of an alignment film formed on the whole curvature surface of a lenticular pattern and a method for manufacturing the same.

BACKGROUND ART

The principle of stereo vision with two eyes facilitates three-dimensional display of a three-dimensional image. The binocular disparity due to the two eyes which are apart from each other by about 65 mm is one of the most important factors for stereocognosy.

Once the different two-dimensional images inputted through the right and left eyes respectively are transmitted to the brain, the brain combines the images together thereby reproducing the depth and reality of the original three-dimensional image. The technology creating a three-dimensional image by means of the binocular vision is called stereography. 3D display apparatus is an apparatus to which the stereography is applied.

The 3D display apparatus may comprise a switching lens. The switching lens comprises a birefringent material (e.g., liquid crystal) whose refractive index is changeable upon the mode switching between 2D and 3D which can be performed, for example, by generating or removing electric field.

Under the 2D mode, the switching lens allows the incident light to pass through the lens without any change of its pathway. Under the 3D mode, however, the switching lens changes the pathway of the incident light to provide two different two-dimensional images to the right and left eyes respectively.

The switching lens comprises a plurality of lenticular patterns filled with the liquid crystals.

The liquid crystals within the lenticular patterns need to be exactly aligned to have a certain molecular orientation at the initial stage so that the switching lens can meet the desired optical properties.

An alignment film is generally used to set the initial molecular orientation of the liquid crystals. The alignment film is in direct contact with the liquid crystals and determines the molecular orientation of the liquid crystals. Generally, the alignment film is made by forming a film of a polymer such as polyimide and then rubbing the film with a rubbing cloth.

If a substrate on which a polymer is coated to make an alignment film has a curved shape, the polymer film formed on the substrate also has a curved shape. Such curved shape of the polymer film causes lots of problems when the rubbing process is performed.

For example, U.S. Patent Application Publication No. 2010/0181022 (hereinafter, Prior Art) says that, if a substrate on which liquid crystal molecules have to be oriented is curved, rubbing of the substrate is often irreproducible. Nevertheless, the Prior Art still suggests a method for making an alignment film by coating a polymer film on a lenticular structure and then rubbing the polymer film.

The Prior Art has lots of drawbacks as follows.

First, when a polymer solution is coated on a structure having a plurality of lenticular patterns (concave lens patterns) to form a polymer film, the polymer solution flows down along the surface of the patterns due to the gravity and gets together at the center of the each pattern. As a result, the thickness deviation of the polymer film on the curvature surface of the each lenticular pattern deviates from the acceptable range. Further, a certain portion of the curvature surface of the lenticular pattern even may not be coated with the polymer solution, which causes the defective molecular orientation of the liquid crystals.

Secondly, when the polymer film is rubbed with a rubbing cloth, a portion of the structure, especially the mountain portions between the neighboring concave lens patterns, may be damaged by the rubbing cloth thereby causing the defective molecular orientation of the liquid crystals.

DISCLOSURE OF INVENTION

Technical Problem

Therefore, the present invention is directed to a switching lens for a display apparatus and a method for manufacturing the same capable of preventing these limitations and drawbacks of the related art.

An aspect of the present invention is to provide a to a switching lens having liquid crystals of highly uniform orientation which can be obtained by minimizing the thickness deviation of an alignment film formed on the whole curvature surface of a lenticular pattern.

Another aspect of the present invention is to provide a method for manufacturing to a switching lens having liquid crystals of highly uniform orientation which can be obtained by minimizing the thickness deviation of an alignment film formed on the whole curvature surface of a lenticular pattern.

Solution to Problem

In accordance with the one aspect of the present invention, there is provided a switching lens for a display apparatus, the switching lens comprising a first film, a resin layer on the first film, the resin layer comprising a lenticular pattern, a first alignment film on the resin layer, a second film, a second alignment film on the second film, and liquid crystals between the first and second alignment films, wherein the first alignment film is a photo-alignment film comprising a photosensitive polymer, the first alignment film covers whole curvature surface of the lenticular pattern of the resin layer, and the first alignment film has a maximum thickness equal to or less than 0.01 times a maximum radius of curvature of the lenticular pattern.

In accordance with another aspect of the present invention, there is provided a method for manufacturing a method for manufacturing a switching lens for a display apparatus, the method comprising preparing an upper plate, preparing a lower plate, and bonding the upper and lower plates, wherein the preparing the upper plate comprises forming a resin layer on a first film, processing a surface of the resin layer such that the resin layer has a lenticular pattern, forming a first alignment film with a photosensitive polymer on the resin layer in such a way that the first alignment film covers whole curvature surface of the lenticular pattern of the resin layer and the first alignment film has a maximum thickness equal to or less than 0.01 times a maximum radius of curvature of the lenticular pattern, and dispensing liquid crystals on the first alignment film, wherein the preparing the lower plate comprises forming a second alignment film on a second film, and wherein the upper and lower plates are bonded to each other in such a way that the second alignment film directly contacts the liquid crystals.

Advantageous Effects of Invention

According to the present invention, the thickness deviation of an alignment film formed on the whole curvature surface of each lenticular pattern within a switching lens can be minimized, and thus the molecular orientation uniformity of the liquid crystals dispensed onto the alignment film can be maximized. As a result, the switching lens of the present invention can have the desired optical properties.

Other advantages of the present invention will be described below in detail together with the related technical features.

MODE FOR THE INVENTION

For the following description of the embodiments of the present invention, if a first structure is described as being formed (or disposed) on a second structure, the first and second structures may be in contact with each other, or there may be an additional structure(s) interposed between the first and second structures. However, if the first structure is described as being formed (or disposed) right on the second structure, it is limited to the case where the first and second structures are in contact with other.

Hereinafter, a switching lens according to the first embodiment of the present invention will be described in detail with reference to theFIGS. 1 to 3.

FIG. 1andFIG. 2are cross-sectional views respectively illustrating 2D mode state and 3D mode state of a display apparatus comprising a switching lens according to the first embodiment of the present invention.

As illustrated inFIG. 1andFIG. 2, the display apparatus comprises a switching lens100according to the first embodiment of the present invention, a display panel200, and an adhesive layer300between the switching lens100and display panel200.

The switching lens100comprises an upper plate110and a lower plate120, the upper and lower plates110and120being bonded together.

The upper plate110comprises a first film111, a first transparent electrode112on the first film111, a resin layer113on the first transparent electrode112, a first alignment film114on the resin layer113, and liquid crystals115on the first alignment film114.

The resin layer113has a plurality of lenticular patterns. The lenticular patterns may be cylindrical lens patterns. The first alignment film114is a photo-alignment film comprising a photosensitive polymer.

As illustrated inFIG. 3, the first alignment film114covers whole curvature surface113aof the each lenticular pattern of the resin layer113, and the first alignment film114has a maximum thickness T equal to or less than 0.01 times a maximum radius of curvature R of the lenticular pattern. In other words, according to the embodiment of the present invention, the first alignment layer114is formed on the resin layer113to have uniform thickness over the whole curvature surface113aof the lenticular patterns, and thus the uniformity of the initial molecular orientation of the liquid crystals115whose molecular orientation is determined by, at least in part, the first alignment film114can be improved. Consequently, the switching lens100of the embodiment of the present invention can satisfy the optical properties required in the field of the three-dimensional display apparatus.

The lower plate120comprises a second film121, a second transparent electrode122on the second film121, and a second alignment film123on the second transparent electrode122.

The upper and lower plates110and120are bonded to each other through a laminating process in such a way that the liquid crystals115of the upper plate110directly contacts the second alignment film123of the lower plate120.

The initial molecular orientation of the liquid crystals115disposed between the first and second alignment films114and123is determined as shown inFIG. 1by the first and second alignment films114and123. As an electric field is generated between the first and second transparent electrodes112and122, the molecular orientation of the liquid crystals115is changed into the state as illustrated inFIG. 2, and thus the refractive index of the liquid crystals115is changed. For example, a switching to 3D mode can be performed by generating electric field between the first and second transparent electrodes112and122.

Under the 2D mode, the switching lens100of the embodiment of the present invention allows the incident light to pass through the lens100without any change of its pathway. Under the 3D mode, however, the switching lens100changes the pathway of the incident light to provide two different two-dimensional images to the right and left eyes respectively.

The display panel200is a panel including, but not limited to, a PDP panel, a LCD panel, and an OLED panel, which provides 2D image under 2D mode and 3D image (i.e., left image and right image) under 3D mode.

The adhesive layer300for bonding the switching lens100and display panel200together may be formed of a transparent pressure-sensitive adhesive.

Hereinafter, a switching lens according to the second embodiment of the present invention will be described in detail with reference to theFIGS. 4 and 5. The same reference numerals as those of the first embodiment of the present invention will be used to refer to the same or like parts.

FIG. 4andFIG. 5are cross-sectional views respectively illustrating 2D mode state and 3D mode state of a display apparatus comprising a switching lens according to the second embodiment of the present invention.

As illustrated inFIG. 4andFIG. 5, the display apparatus comprises a switching lens100according to the second embodiment of the present invention, a display panel200, and an adhesive layer300between the switching lens100and display panel200.

The switching lens100comprises an upper plate110, a lower plate120bonded to the upper plate110, a polarization switching unit130, and an adhesive layer140between the lower plate120and the polarization switching unit130.

The upper plate110comprises a first film111, a resin layer113on the first film111, a first alignment film114on the resin layer113, and cured reactive mesogens116on the first alignment film114.

The resin layer113has a plurality of lenticular patterns. The lenticular patterns may be cylindrical lens patterns. The first alignment film114is a photo-alignment film comprising a photosensitive polymer.

As illustrated inFIG. 3, the first alignment film114covers whole curvature surface113aof the each lenticular pattern of the resin layer113, and the first alignment film114has a maximum thickness T equal to or less than 0.01 times a maximum radius of curvature R of the lenticular pattern. In other words, according to the embodiment of the present invention, the first alignment layer114is formed on the resin layer113to have uniform thickness over the whole curvature surface113aof the lenticular patterns, and thus the uniformity of the orientation of the cured reactive mesogens116can be improved. Consequently, the switching lens100of the second embodiment of the present invention can satisfy the optical properties required in the field of the three-dimensional display apparatus.

The lower plate120comprises a second film121and a second alignment film123on the second film121.

The upper and lower plates110and120are bonded to each other through a laminating process in such a way that the cured reactive mesogens116of the upper plate110directly contacts the second alignment film123of the lower plate120.

The polarization switching unit130bonded to the lower plate120through the adhesive layer140comprises third and fourth films131and132, first and second transparent electrodes133and134formed on the third and fourth films131and132respectively, third and fourth alignment films135and136formed on the first and second transparent electrodes133and134respectively, and liquid crystals137between the third and fourth alignment films135and136.

The initial molecular orientation of the liquid crystals137disposed between the third and fourth alignment films135and136is determined as shown inFIG. 4by the third and fourth alignment films135and136. As an electric field is generated between the first and second transparent electrodes133and134, the molecular orientation of the liquid crystals137is changed into the state as illustrated inFIG. 5, and thus the polarization direction of the light is changed when it passes through the polarization switching unit130.

The polarization direction of the light which passed through the polarization switching unit130while no electric field was applied between the first and second transparent electrodes133and134is different from that of the light which passed through the polarization switching unit130while a certain electric field was applied between the first and second transparent electrodes133and134. The cured reactive mesogens116have different refractive indexes with respect to the lights of different polarization directions.

Consequently, under the 2D mode, the switching lens100of the second embodiment of the present invention allows the incident light to pass through the lens100without any change of its pathway. Under the 3D mode, however, the switching lens100changes the pathway of the incident light to provide two different two-dimensional images to the right and left eyes respectively.

For example, a switching to 3D mode can be performed by generating electric field between the first and second transparent electrodes133and134.

The display panel200is a panel including, but not limited to, a PDP panel, a LCD panel, and an OLED panel, which provides 2D image under 2D mode and 3D image (i.e., left image and right image) under 3D mode.

The adhesive layer300for bonding the switching lens100and display panel200together may be formed of a transparent pressure-sensitive adhesive.

Hereinafter, a method for manufacturing a switching lens according to the embodiments of the present invention will be described in detail with reference to theFIG. 6.

FIG. 6schematically shows an apparatus for manufacturing a switching lens according to an embodiment of the present invention.

The method for manufacturing a switching lens according to the embodiments of the present invention comprises preparing an upper plate, preparing a lower plate, and bonding the upper and lower plates together.

The step of preparing the upper plate comprises forming a resin layer on a first film11, processing a surface of the resin layer such that the resin layer has a lenticular pattern, forming a first alignment film with a photosensitive polymer on the resin layer in such a way that the first alignment film covers whole curvature surface of the lenticular pattern of the resin layer, and dispensing liquid crystals on the first alignment film.

More specifically, the first film11is supplied from the first feeding roll FR1. The first film11used for manufacturing a switching lens described above as the first embodiment of the present invention comprises a base film and a transparent electrode. On the other hand, the first film11used for manufacturing a switching lens described above as the second embodiment of the present invention consists only of a base film.

A resin13is coated on the first film11supplied from the first feeding roll FR1to form the resin layer on the first film11. Optionally, surface modification of the first film11and/or cleaning thereof can be performed before the resin13is coated thereon.

Then, the surface of the resin layer is processed by the master roll MR while the first film11is supported by the supporting roll SR1such that the resin layer has a plurality of lenticular patterns at its surface, and the resin layer having the lenticular patterns is cured at the UV curing section30. The master roll MR may have cylindrical convex lens patterns.

Subsequently, a solution14comprising a photosensitive polymer is coated on the resin layer having the lenticular patterns at its surface, dried at the drying section60, and then irradiated with a light, e.g., polarized UV, at the polarized UV irradiating section70to complete the first alignment film.

The solution14may further comprise an initiator and/or a coupling agent in addition to the photosensitive polymer, and may have viscosity of 1 to 3 cps. According to the one embodiment of the present invention, the solution14comprises solid components (solute) of 1 to 5 wt % and solvent of 95 to 99 wt %. The photosensitive polymer may be PI, PMMA, PVA, PNB, or copolymer thereof, which has at least one photosensitive functional group selected from the group consisting of azobenzene, cinamoyl, cumarine, chalcone, and polyimide C—N.

The solution14may be coated on the resin layer by means of slot die coating method, spray coating method, bar coating method, dipping method, and so on.

The process for drying the solution14may be performed at 90 to 110° C. for 1 to 2 minutes, and the polarized UV with which the dried solution14is irradiated may have wavelength of about 313 nm and energy density of several or several tens of mJ/cm2.

According to the embodiment of the present invention, the first alignment film can be formed on the resin layer having the lenticular patterns without the rubbing process, and thus the risk that some portions of the resin layer, especially the mountain portions between the neighboring concave lens patterns, will be damaged by the rubbing cloth can be thoroughly removed.

Meanwhile, there exists a risk that the solution14will flow down along the surfaces of the plurality of lenticular patterns (i.e., concave lens patterns) due to the gravity when coated on the resin layer having the patterns. Such risk might cause the thickness deviation of the alignment film on the curvature surfaces of the lenticular patterns to deviate from the acceptable range, and further cause a certain portion of the curvature surface of the lenticular pattern even not to be covered with alignment film.

According to the embodiment of the present invention, the solution14coated on the resin layer is prevented or restrained as much as possible from flowing down due to the gravity so that the first alignment film formed on the resin layer can cover the whole curvature surfaces of the lenticular patterns of the resin layer and have a maximum thickness equal to or less than 0.01 times a maximum radius of curvature of the lenticular pattern.

Hereinafter, the methods according to the embodiments of the present invention to prevent or restrain the solution14coated on the resin layer from flowing down due to the gravity will be described in detail.

First, the resin layer the surface of which has been processed to form the lenticular patterns may be preheated at the heating section50before the solution14comprising a photosensitive polymer is coated on the resin layer. When the solution14is coated on the preheated resin layer of relatively high temperature, the solution14gets to be dried right after it becomes in contact with the preheated resin layer. Consequently, the solution14coated on the resin layer can be prevented or restrained as much as possible from flowing down due to the gravity.

Secondly, the step of coating the solution14and the step of drying the solution14may be performed at least in part simultaneously. In this case, the step of drying the solution14may be performed by supplying the hot air from the drying section60toward the backside of the first film11so that the drying step does not affect the coating step.

Thirdly, before the solution14being irradiated with the polarized UV after dried, the position of the solution14may be adjusted by means of an adjusting roll AR having a plurality of convex lens patterns of the same shape and size as those of the convex lens patterns of the master roll MR used to process the surface of the resin layer to form the lenticular patterns. In case the solution14falls down along the curvature surface of the lenticular pattern to a certain degree, the adjustment of the position of the solution14with the adjusting roll AR can restore the solution14to the original position thereby improving the thickness uniformity of the first alignment film. When the adjustment of the position of the solution14with the adjusting roll AR is performed, the first film11may be supported by the supporting roll SR2. Optionally, the supporting roll SR2may be heated so that the step of adjusting the position of the solution14can be performed simultaneously with the step of drying the solution14.

Fourthly, before the solution14is coated on the resin layer, the surface of the resin layer having the lenticular patterns, i.e., the curvature surface of the lenticular patterns, may be treated with plasma at the surface treatment section40so that the solution14can be mechanically/physically prevented from falling down due to the gravity after coated.

Each of the aforementioned methods can be used singly or in combination with other(s) to form the first alignment film which covers the whole curvature surface of the lenticular patterns of the resin layer and has the maximum thickness equal to or less than 0.01 times a maximum radius of curvature of the lenticular patterns.

After the first alignment film is completed through the polarized UV irradiation, liquid crystals are dispensed thereon. The liquid crystals15of the switching lens according to the first embodiment of the present invention as described above are conventional liquid crystals the molecular orientation of which is changeable by the electric field applied thereto. On the other hand, the liquid crystals15of the switching lens according to the second embodiment of the present invention are reactive mesogens the molecular orientation of which is set in a certain direction at the initial alignment stage and then fixed through the subsequent curing process.

Meanwhile, the step of preparing the lower plate comprises forming the second alignment film on the second film21.

More specifically, the second film21is supplied from the second feeding roll FR2.

The second film21of the switching lens according to the first embodiment of the present invention as described above comprises a base film and a transparent electrode. On the other hand, the second film21of the switching lens according to the second embodiment of the present invention comprises only a base film.

A solution23comprising a photosensitive polymer is coated on the second film21and dried at the drying section80. Subsequently, the dried solution23is irradiated with polarized UV at the polarized UV irradiating section90to complete the second alignment film.

Optionally, the second alignment film may be formed through a rubbing process since it is formed on the plane surface of the second film21. That is, to form the second alignment film, a solution23comprising a polymer such as PI may be coated on the second film21, dried at the drying section80, and then rubbed with a rubbing cloth.

Once the upper and lower plates are prepared, they are bonded to each other by means of the first and second laminating rolls LR1and LR2. Through the bonding process, the liquid crystals become in contact with the second alignment film.

The method for manufacturing the switching lens according to the first embodiment of the present invention further comprises performing a sealing process after the laminating process (i.e., bonding process) so that any leakage of the liquid crystals15can be prevented.

On the other hand, the method for manufacturing the switching lens according to the second embodiment of the present invention further comprises curing the reactive mesogens15after the laminating process, and then bonding the polarization switching unit to the lower plate with an adhesive. The step of curing the reactive mesogens may be performed by means of a light such as UV.

Those skilled in the art will appreciate that various modifications, additions and substitutions are possible, without departing from the scope and spirit of the invention. Accordingly, the present invention includes all alternations and modifications that fall within the scope of inventions described in claims and equivalents thereto.