JP2010134404A - Stereoscopic image display and method for producing the same - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To provide a stereoscopic image display capable of reliably preventing a crosstalk phenomenon while minimizing a decrease in the luminance of a displayed image. <P>SOLUTION: The stereoscopic image display includes: an image display panel 1 that displays right-eye images and left-eye images in a regularly mixed pattern in a plane; a retardation element 3 disposed on an image output side of the image display panel 1 and including right-eye-image display portions 3a, corresponding to the right-eye images, and left-eye-image display portions 3b, corresponding to the left-eye images, which cause polarization so that the right-eye images and the left-eye images may be in different polarization state each other; a polarizing plate 2 disposed between the image display panel 1 and the retardation element 3; and a light-shielding layer 4 disposed between the image display panel 1 and the polarizing plate 2 so as to correspond to regions including boundaries between the right-eye-image display portions and the left-eye-image display portions of the retardation element 3. <P>COPYRIGHT: (C)2010,JPO&INPIT

Description

  The present invention relates to a stereoscopic image display device that displays a stereoscopic image using a right-eye image and a left-eye image, and a method for manufacturing the same.

  Conventionally, as a stereoscopic image display device that displays a stereoscopic image, for example, a configuration shown in FIG. 14 is known (see, for example, Patent Document 1). The stereoscopic image display apparatus shown in the figure includes an image display panel 51 made up of a liquid crystal panel and the like, and a phase difference element 52 arranged on the image output surface side, and the viewer displays the contents of display output by the polarizing glasses 53. It is comprised so that it may visually observe using. More specifically, the image display panel 51 displays the right-eye image R and the left-eye image L in-plane so that, for example, the right-eye image R and the left-eye image L are alternately displayed for each horizontal line. Display regularly mixed. The phase difference element 52 includes a right-eye image display unit 52R corresponding to the right-eye image R and a left-eye image display unit 52L corresponding to the left-eye image L, which are alternately arranged for each horizontal line. It is arranged in. For example, the right-eye image display unit 52R is unidirectional linearly polarized light (for example, rising right), whereas the left-eye image display unit 52L is rotated by 90 ° so as to be orthogonal thereto. Each is configured to realize different polarization states, such as realizing (for example, rising to the left). A viewer puts on the image display panel 51 and the phase difference element 52 with polarized glasses 53 having different right and left polarization angles suitable for each image. Therefore, for the viewer, the right eye image R is incident on the right eye and the left eye image L is incident on the left eye independently. That is, through the right-eye glasses 53R having a rising polarization angle, the left-eye image L of the even line whose polarization angle is rotated 90 ° upward by the left-eye image display unit 52L of the phase difference element 52 cannot be seen. Only the right-eye image R of the odd-numbered lines with matching corners can be seen. On the other hand, through the left eyeglasses 53L having a rising left-handed polarization angle, the right-eye image display unit 52R of the phase difference element 52 cannot see the odd-line right-eye image R whose polarization angle is rotated 90 ° upwardly, and the polarized light is polarized. The left-eye video L of even lines with matching corners can be seen. In addition to the above-described configuration, there are various types of stereoscopic image display devices that separately display the left and right images and synthesize them as stereoscopic images using polarized glasses.

In such a stereoscopic image display apparatus, the occurrence of a so-called crosstalk phenomenon may be a problem. The “crosstalk phenomenon” refers to, for example, when the viewer looks from an oblique direction rather than the front, the right-eye image R passes through the left-eye image display unit 52L, or the left-eye image L is the right-eye image display unit 52R. Or the like, an image captured by the viewer becomes unclear and a problem such as a weak stereoscopic effect occurs.
For this reason, some stereoscopic image display devices include a light shielding layer that shields light at the boundary between the right-eye image display unit 52R and the left-eye image display unit 52L in the phase difference element 52 ( For example, see Patent Document 2.) More specifically, for example, if the right-eye image display unit 52R and the left-eye image display unit 52L are alternately arranged for each horizontal line, a region portion having a predetermined width including the boundary between the display units 52R and 52L. A striped light shielding layer is disposed so as to be located only on the surface. It is conceivable that the light shielding layer is formed by projecting a black material having a function of shielding light from the surface of the phase difference element 52. If such a light shielding layer is provided, for example, even when the viewer views from an oblique direction, the right eye image R passes through the left eye image display unit 52L by being shielded by the light shielding layer, The left-eye image L does not pass through the right-eye image display unit 52R. That is, the occurrence of the crosstalk phenomenon can be prevented beforehand.

JP 2002-196281 A JP 2002-185983 A

By the way, it is preferable that the formation width of the light shielding layer is wide in order to prevent the occurrence of the crosstalk phenomenon. That is, if the formation width of the light shielding layer is too narrow, the crosstalk light may not be sufficiently blocked.
On the other hand, when the formation width of the light shielding layer is increased, the light passing therethrough is reduced, leading to a decrease in luminance of the display image.
Therefore, the formation width of the light shielding layer should be set to a size that can suppress the decrease in luminance of the display image as much as possible while preventing the occurrence of the crosstalk phenomenon.

  However, in the prior art described in Patent Document 2, a light shielding layer is directly formed on the front side or the back side of the film-like retardation element. For this reason, it is not always possible to appropriately deal with an event having a trade-off relationship (prevention of crosstalk phenomenon) and prevention of luminance reduction of a display image.

  Therefore, the present invention provides a stereoscopic image display device and a method for manufacturing the same, which can prevent the occurrence of crosstalk phenomenon with a light-shielding layer and can suppress a decrease in luminance of a display image as much as possible. The purpose is to do.

  The present invention provides a stereoscopic image display device devised to achieve the above object, an image display panel for displaying a right-eye image and a left-eye image mixed regularly in a plane, and the image display panel. The right-eye image display unit corresponding to the right-eye image and the left-eye image, which are arranged on the image output surface side and are polarized so that the right-eye image and the left-eye image have different polarization states. A phase difference element having a corresponding left-eye image display unit, a polarizing plate disposed between the image display panel and the phase difference element, the right-eye image display unit and the left-eye image in the phase difference element The stereoscopic image display device includes a light shielding layer disposed between the image display panel and the polarizing plate so as to correspond to a region including a boundary with the display unit.

  In the stereoscopic image display device having the above configuration, the light shielding layer is disposed on the image display panel side of the polarizing plate. That is, as compared with the case where the light shielding layer is located on the image output surface side (the side far from the image display panel) of the polarizing plate, for example, the light shielding layer is formed directly on the surface of the retardation element. The light shielding layer is present at a position close to the image display panel. Therefore, if the occurrence of the crosstalk phenomenon is prevented for the same viewing angle, the formation width of the light shielding layer may be smaller than when the light shielding layer is located on the image output surface side of the polarizing plate.

  According to the present invention, compared to the case where the light shielding layer is located on the image output surface side of the polarizing plate, it is possible to reduce the formation width of the light shielding layer, thereby preventing the occurrence of a crosstalk phenomenon. Even in such a case, a reduction in luminance of the display image can be suppressed as much as possible.

It is explanatory drawing which shows the 1st schematic structural example of the stereo image display apparatus which concerns on this invention. It is explanatory drawing which shows the 2nd schematic structural example of the stereo image display apparatus which concerns on this invention. It is explanatory drawing which shows one specific example of the outline | summary of the light shielding layer formation process in the manufacturing method of the three-dimensional image display apparatus which concerns on this invention. It is explanatory drawing which shows the 1st example of the outline | summary of the positioning process in the manufacturing method of the stereo image display apparatus which concerns on this invention. It is explanatory drawing which shows the 2nd example of the outline | summary of the positioning process in the manufacturing method of the stereo image display apparatus which concerns on this invention. It is explanatory drawing which shows one specific example of the relationship between the adhesive hardness of the adhesive bond layer used with the three-dimensional image display apparatus which concerns on this invention, and adhesive layer retention strength. It is explanatory drawing which shows a specific example of the adhesive elasticity and adhesive viscosity of the bonding agent layer used with the three-dimensional image display apparatus which concerns on this invention. It is explanatory drawing which shows a specific example of the creep characteristic of the adhesive bond layer used with the three-dimensional image display apparatus which concerns on this invention. It is explanatory drawing which shows one specific example of the bonding process in the manufacturing method of the three-dimensional image display apparatus which concerns on this invention, and is a figure which shows the specific example of the pressure bonding using the roller for bonding. It is explanatory drawing (the 1) which shows the outline | summary of the effect of the stereo image display apparatus which concerns on this invention concretely. It is explanatory drawing (the 2) which shows the outline | summary of the effect effectively of the stereo image display apparatus which concerns on this invention. It is explanatory drawing (the 3) which shows the outline | summary of the effect of the stereo image display apparatus which concerns on this invention concretely. It is explanatory drawing (the 4) which shows the outline | summary of the effect of the stereo image display apparatus which concerns on this invention concretely. It is explanatory drawing which shows the basic schematic structural example of the conventional stereo image display apparatus.

Hereinafter, modes for carrying out the present invention (hereinafter referred to as “embodiments”) will be described. The description will be given in the following order.
1. Schematic configuration of stereoscopic image display device (first schematic configuration example, second schematic configuration example)
2. Manufacturing method of stereoscopic image display device (annealing process, light shielding layer forming process, positioning process, bonding process)
3. Effects in this embodiment

<1. Schematic configuration of stereoscopic image display device>
First, a schematic configuration of the stereoscopic image display device will be described.

[1-1. First schematic configuration example]
FIG. 1 is an explanatory diagram showing a first schematic configuration example of a stereoscopic image display apparatus according to the present invention.
The stereoscopic image display device shown in the figure includes an image display panel 1, a polarizing plate 2, a retardation element 3, a light shielding layer 4, a first bonding agent layer 5, an air layer 6, and a second bonding agent layer 7. And an antireflection film 8 and a third bonding agent layer 9.

  The image display panel 1 is composed of, for example, a liquid crystal panel, and the right-eye image and the left-eye image are regularly regulated in a plane so that the right-eye image and the left-eye image are alternately displayed for each horizontal line. Are mixed and displayed. However, as long as the image for the right eye and the image for the left eye are regularly mixed in the plane, the display may be performed in a mixed manner other than the alternate display for each horizontal line. Moreover, it is not necessarily configured using a liquid crystal panel, and may be configured using another display device such as an organic EL (Electro Luminescence) display panel.

  The polarizing plate 2 is disposed between the image display panel 1 and the phase difference element 3 on the image output surface side of the image display panel 1 with respect to the image display panel 1. Only light that vibrates in a predetermined direction is transmitted. Here, the “image output surface side” refers to the panel surface side on which an image is displayed and output, and specifically refers to the side facing the viewer viewing the image. For example, if the image display panel 1 is a transmissive liquid crystal panel, the polarizing plate 2 is another polarizing plate (provided that the polarizing plate 2 and the image display panel 1 are opposed to each other) It is assumed that a crossed Nicol state is formed in a pair with (not shown).

The phase difference element 3 includes a right-eye image display unit 3a corresponding to the right-eye image and a left-eye image display unit 3b corresponding to the left-eye image. Similar to the left-eye image, the image display panel 1 is arranged on the image output surface side so as to be regularly mixed in the surface (for example, alternately for each horizontal line). More specifically, a retardation layer is formed on a support substrate 3c made of a glass material or a film having no birefringence, and the retardation layer realizes a polarization state corresponding to an image for the right eye and for the left eye. By having a portion that realizes a polarization state corresponding to an image, functions as the right-eye image display unit 3a and the left-eye image display unit 3b are realized. That is, the phase difference element 3 is configured such that each of the right-eye image display unit 3a and the left-eye image display unit 3b realizes different polarization states.
Specifically, for example, the polarization directions of the right-eye image display unit 3a and the left-eye image display unit 3b are orthogonal to each other so as to match the vertical pitch of each horizontal line in the image display panel 1. It is conceivable to use one alternately formed on the support substrate 3c having a thickness of about 0.7 mm. Also, for example, a TAC (triacetyl cellulose) film having no birefringence and a stretched PVA film having a retardation function are laminated on the support substrate 3c via an adhesive, and then a linear resist is applied. After the phase difference function other than the portion is lost, the right-eye image display unit 3a and the left-eye image display unit 3b are alternately formed, and a protective member film having no birefringence is provided on the resist coating side. It is conceivable to use one that is bonded to the display panel 1 or one in which a liquid crystal polymer layer is uniaxially oriented on the support substrate 3c.

The light shielding layer 4 is disposed so as to correspond only to a region including the boundary between the right-eye image display unit 3a and the left-eye image display unit 3b in the phase difference element 3 in order to prevent the occurrence of the crosstalk phenomenon. Is. More specifically, for example, if the right-eye image display unit 3a and the left-eye image display unit 3b are alternately arranged for each horizontal line, an area portion having a predetermined width including the boundary between the display units 3a and 3b. It is arranged in stripes so as to be located only in the area. Such a light shielding layer 4 is configured by selectively forming a black material such as a carbon material having a function of shielding light, for example, in a stripe shape at a height of about 10 to 15 μm. It is possible.
The light shielding layer 4 is disposed so as to correspond to the boundary portion between the right-eye image display unit 3 a and the left-eye image display unit 3 b in the phase difference element 3, but the surface of the phase difference element 3. It is assumed that it is disposed not at the top but at a position closer to the image display panel 1 than the polarizing plate 2.

The first bonding agent layer 5 is interposed between the image display panel 1 and the polarizing plate 2 and bonds them together. That is, since the light shielding layer 4 is formed on the surface of the polarizing plate 2 on the image display panel 1 side, the first bonding agent layer 5 forms the light shielding layer 4 in the image display panel 1 and the polarizing plate 2. It is interposed between the surface side.
More specifically, the first bonding agent layer 5 is provided between the image display panel 1 and the formation surface side of the light shielding layer 4 in the polarizing plate 2 except between the top surface of the light shielding layer 4 and the image display panel 1. Intervene. Accordingly, since the space between the top surface of the light shielding layer 4 and the image display panel 1 is removed, the first bonding agent layer 5 is not interposed therebetween.
However, although it is desirable that the space between the top surface of the light shielding layer 4 and the image display panel 1 is removed for the reasons described later, it is not always necessary to remove the space between them. In addition, it may be interposed so as to fill the unevenness formed by the light shielding layer 4 including these spaces. Or, conversely, the first bonding agent layer 5 is interposed only between the top surface of the light shielding layer 4 and the image display panel 1, and the first bonding agent layer 5 is not formed on the portion where the light shielding layer 4 is not formed. It is also conceivable to have a space that is not filled.
Here, the “bonding agent layer” refers to a layer formed by the bonding agent. The “bonding agent” refers to a material interposed between members for bonding, and specifically corresponds to an adhesive or a pressure-sensitive adhesive. Therefore, the “bonding agent layer” includes a layer formed of an adhesive and a layer formed of an adhesive.
On the other hand, in the stereoscopic image display device described in this embodiment, the first bonding agent layer 5 is made of a transparent gel-like acrylic pressure-sensitive adhesive and has a layer thickness of 25 to 100 μm for the reasons described later. It is assumed that Furthermore, the hardness of the pressure-sensitive adhesive is in the range of more than 0 and 350,000 μN or less, and the holding force after bonding at 40 ° C. is 8 to 20 N / 20 mm.
Further, in the stereoscopic image display device described in the present embodiment, the first bonding agent layer 5 satisfies the following conditions in addition to the above-described conditions or separately from the above-described conditions (not the above-described conditions). It may be a thing. That is, the first bonding agent layer 5 is made of a transparent gel-like acrylic pressure-sensitive adhesive for the reason described later, and the storage rigidity at 30 to 70 ° C. is in the range of greater than 0 to 70000 Pa or less, and the loss rigidity is Is in the range of more than 0 and 20000 Pa or less. And by satisfy | filling these conditions, it is comprised so that a creep characteristic may be 0.3 mm or less.
The “pressure-sensitive adhesive” means a semi-solid having a high viscosity and a low elastic modulus from the beginning and whose state does not change even after the bonding is formed, that is, a solidification process is not required.

  The air layer 6 is formed by the absence of the first bonding agent layer 5 between the top surface of the light shielding layer 4 and the image display panel 1. That is, the air layer 6 is a space that is not filled with the first bonding agent layer 5.

The second bonding agent layer 7 is interposed between the polarizing plate 2 and the retardation element 3 and bonds them together.
Similarly to the first bonding agent layer 5, the second bonding agent layer 7 is made of a transparent gel acrylic adhesive and has a layer thickness of 25 to 100 μm. Furthermore, the hardness of the pressure-sensitive adhesive is in the range of more than 0 and 350,000 μN or less, and the holding force after bonding at 40 ° C. is 8 to 20 N / 20 mm.
Alternatively, as in the case of the first bonding agent layer 5, it is made of a transparent gel-like acrylic adhesive, and the storage rigidity at 30 to 70 ° C. is in the range of greater than 0 to 70000 Pa or less, and the loss rigidity is It is in the range of more than 0 and 20000 Pa or less. And by satisfy | filling these conditions, it is comprised so that a creep characteristic may be 0.3 mm or less.

The antireflection film 8 is disposed so as to cover the image output surface side of the phase difference element 3, and prevents reflection of light on the image output surface, thereby improving the light transmittance.
The third bonding agent layer 9 is for bonding the antireflection film 8 to the phase difference element 3 (more specifically, the support base material 3c constituting the phase difference element 3). It is conceivable to use a layer made of an agent or an adhesive.

In such a stereoscopic image display device according to the first schematic configuration example, the phase difference element 3 for causing a stereoscopic image to appear is disposed on the image output surface side of the polarizing plate 2 via the second bonding agent layer 7. Has been. The phase difference element 3 includes a right-eye image display unit 3a corresponding to the right-eye image and a left-eye image display unit 3b corresponding to the left-eye image, each realizing a different polarization state. It is supposed to be.
Therefore, if the viewer wears polarized glasses with different right and left polarization angles suitable for each image, the right eye image and the left eye image for the viewer are incident independently for the viewer. As a result, the stereoscopic image becomes visible.

  In the stereoscopic image display device according to the first schematic configuration example, the right-eye image display unit 3a is provided between the image display panel 1 and the phase difference element 3, more specifically between the image display panel 1 and the polarizing plate 2. The light shielding layer 4 is disposed corresponding to the boundary between the left eye image display unit 3b. Therefore, for example, even when the viewer views from an oblique direction, the right-eye image passes through the left-eye image display unit 3b and the left-eye image is the right-eye image by being shielded by the light-shielding layer 4. It does not pass through the display unit 3a. That is, it is possible to prevent the occurrence of the crosstalk phenomenon.

  Further, in the stereoscopic image display device according to the first schematic configuration example, the area between the image display panel 1 and the polarizing plate 2 is bonded via the first bonding agent layer 5, and between the polarizing plate 2 and the retardation element 3. Is bonded via the second bonding agent layer 7. That is, the bonding location by the 1st bonding agent layer 5 and the 2nd bonding agent layer 7 has also extended in the image display area in the image display panel 1. FIG. Therefore, unlike the case of fixing only outside the image display area of the image display panel 1, sufficient adhesion in the vicinity of the central portion of the image display area cannot be obtained, or the uniformity of the distance between each is impaired. There is nothing to be done. Therefore, it is possible to avoid the occurrence of moiré phenomenon, Newton rings (interference fringes), and the like that can be a cause of image quality degradation of the display image.

And in that case, even if there are irregularities due to the light shielding layer 4 between the image display panel 1 and the polarizing plate 2 for the bonding by the first bonding agent layer 5, the concave portion without the light shielding layer 4, That is, the first bonding agent layer 5 is interposed in the portion where light is transmitted so as to follow the shape of the concave portion. That is, the concave portion is filled with the first bonding agent layer 5 and an air layer is not generated. Therefore, the image quality of the display image is not deteriorated due to the light refraction action in the air layer.
On the other hand, if the first bonding agent layer 5 is interposed so as to exclude the space between the top surface of the light shielding layer 4 and the image display panel 1, the space between the top surface of the light shielding layer 4 and the image display panel 1 is used. The air layer 6 which is a space not filled with the first bonding agent layer 5 exists. Therefore, the air layer 6 acts so as to release distortion that may occur at the time of bonding, and as a result, unevenness of the in-plane bonding stress distribution state after bonding is reduced. Further, the location where the air layer 6 exists is a location between the top surface of the light shielding layer 4 and the image display panel 1, that is, a location where light is blocked by the light shielding layer 4. Therefore, even if the air layer 6 is present, unlike the case of the concave portion without the light shielding layer 4, it does not cause a deterioration in the image quality of the display image.
That is, when the first bonding agent layer 5 is interposed so as to remove the space between the top surface of the light shielding layer 4 and the image display panel 1 in bonding with the first bonding agent layer 5, unevenness due to the light shielding layer 4 is generated. Even if it exists, it is possible to suppress deterioration in image quality due to in-plane nonuniformity of the stress distribution state by the necessary air layer 6 while suppressing deterioration in image quality due to light refraction in an unnecessary air layer. Therefore, the image display panel 1 and the polarizing plate 2 can be appropriately bonded as a result.

  Moreover, if the thing by an adhesive is used as the 1st bonding agent layer 5 and the 2nd bonding agent layer 7, the cost of adhesive itself can be restrained low compared with the case where an adhesive agent is used, for example. Furthermore, since the pressure-sensitive adhesive does not solidify like an adhesive, the first bonding agent layer 5 itself and the second bonding agent layer 7 themselves have buffering properties against external load. Therefore, for example, even when a load is applied to the image display panel 1 and a crack occurs, the glass substrate can be prevented from scattering, and a protective film or the like that had to be used in the past becomes unnecessary, so that the number of parts can be reduced. Can also be effective. Furthermore, since it is not fixed bonding such as adhesive or UV resin, it can be peeled off and then pasted again in the event of a malfunction, and as a result, it can be realized that the pasting work can be easily performed. It becomes. In addition, if it is based on an adhesive, it is expected that adverse effects on the environment can be suppressed as compared with, for example, the case of using an adhesive containing a volatile solvent.

[1-2. Second schematic configuration example]
FIG. 2 is an explanatory diagram showing a second schematic configuration example of the stereoscopic image display apparatus according to the present invention.
The three-dimensional image display device shown in the figure is different from the above-described first schematic configuration example (see FIG. 1) in that a base sheet 4 a is interposed between the polarizing plate 2 and the light shielding layer 4.

  The base material sheet 4a is made of, for example, a TAC film, and the light shielding layer 4 is projected on the surface thereof. In the configuration including the base material sheet 4a, the light shielding layer 4 is not directly formed on the surface of the polarizing plate 2, but the light shielding layer 4 is formed on the surface of the base material sheet 4a. The base sheet 4a on which the layer 4 is formed is subjected to a manufacturing procedure such as sticking on the surface of the polarizing plate 2. Therefore, for example, compared with the case where the light shielding layer 4 is directly formed on the surface of the polarizing plate 2, the formation of the light shielding layer 4 can be facilitated.

  Such a base material sheet 4a and the light shielding layer 4 formed on the base material sheet 4a are formed in such a manner that the light shielding layer 4 protrudes toward the image display panel 1 and the polarizing plate 2 and the retardation element. Similarly to 3, the second bonding agent layer 7 is used for bonding.

On the other hand, the base material sheet 4a and the base material sheet 4a and the image display panel 1 are bonded together by the first bonding agent layer 5 as in the case of the first schematic configuration example. At this time, the first bonding agent layer 5 is present in a uniform thickness over the entire area of the panel surface including between the top surface of the light shielding layer 4 and the image display panel 1. Therefore, in a portion other than the top surface of the light shielding layer 4 (a portion where the light shielding layer 4 is not formed), a space in which the first bonding agent layer 5 is not filled is provided between the image display panel 1 and the base sheet 4a. Will exist.
However, between the image display panel 1 and the base material sheet 4a, for the reason described later, the first bonding agent layer 5 is made to have a uniform thickness, and the first bonding agent is formed in a portion where the light shielding layer 4 is not formed. Although it is desirable to have a space that is not filled with the layer 5, the space need not necessarily exist. That is, the first bonding agent layer 5 may be interposed so as to fill the unevenness formed by the light shielding layer 4. Or, conversely, it is interposed between the image display panel 1 and the base sheet 4a except for the top surface of the light shielding layer 4 and the image display panel 1, and the top surface of the light shielding layer 4 and the image display panel. It is also conceivable that an air layer 6 exists between the first and second air layers.

In the stereoscopic image display device according to the second schematic configuration example, if there is a space not filled with the first bonding agent layer 5 between the image display panel 1 and the base sheet 4a, the in-plane after bonding The nonuniformity of the bonding stress distribution state is alleviated. That is, for example, due to the unevenness formed by the light shielding layer 4, even if undulation or the like is present on the bonding surface with the image display panel 1, that is, the plane formed by the top surface of the light shielding layer 4, the space is not bonded. It acts to release any distortion that may occur. Therefore, the non-uniformity of the in-plane bonding stress distribution state is alleviated.
In addition, since the first bonding agent layer 5 only needs to be interposed at least on the top surface of the light shielding layer 4, that is, the convex top surface, a space that is not filled with the first bonding agent layer 5 does not exist. Compared to the case, the operation for interposing the first bonding agent layer 5 and the bonding operation using the first bonding agent layer 54 do not become complicated. In other words, for example, a bonding operation or the like can be performed very simply, for example, by adhering the sheet-like first bonding agent layer 5.

  In the second schematic configuration example, points other than those described above are the same as those in the first schematic configuration example.

<2. Manufacturing method of stereoscopic image display device>
Next, a method for manufacturing a stereoscopic image display device having the above configuration will be described.
In manufacturing a stereoscopic image display device, at least an annealing process, a light shielding layer forming process, a positioning process, and a bonding process are included.
Hereinafter, these steps will be described in order.

[2-1. Annealing process]
As described above, the stereoscopic image display device is configured to include the phase difference element 3, and the phase difference element 3 is originally made of a material containing water, and absorbs moisture in the air. There is. Therefore, in order to form a stereoscopic image display apparatus in that state, the phase difference element 3 is bonded, and the front and back surfaces of the phase difference element 3 are sandwiched between light permeable materials such as a glass substrate. If it is sealed with, there is a possibility that the following problems will occur.
For example, the stereoscopic image display apparatus may exceed the equator by sea at the time of transportation after being shipped from the production factory as a product, but the ambient temperature of the product in that case may be 60 to 70 ° C. When placed in such a high temperature environment for a certain period of time or longer, in the stereoscopic image display device, a gas such as water or acetic acid comes out of the phase difference element 3 and becomes a bubble having a size of about 50 μm to 200 μm. It is done. In this case, if the front and back surfaces of the phase difference element 3 are sealed, the bubbles lose their escape, and as a result, the stereoscopic image display device may become a defective product.
Therefore, in manufacturing the stereoscopic image display device, an annealing process is performed on the retardation element 3 prior to performing bonding on the retardation element 3.

In the annealing step, at least one surface of the phase difference element 3, more specifically, the surface on which the right-eye image display unit 3 a and the left-eye image display unit 3 b are formed is sealed. However, the heat treatment is performed on the phase difference element 3 in a state where the phase difference element 3 is released to the atmospheric environment.
The heat treatment is performed for a predetermined time at a predetermined temperature. Specifically, considering that the heat resistant temperature of the phase difference element 3 is about 100 to 120 ° C., the temperature is, for example, 40 to 80 ° C., preferably about 70 ° C., preferably 1 hour to 3 days, preferably It can be performed for about 48 hours.
In addition, what is necessary is just to perform using a well-known technique except the conditions mentioned above in heat processing.

Through an annealing process that performs such heat treatment, it is possible to suppress the generation of bubbles from the phase difference element 3 that is a cause of product defects even when it is placed in a high temperature environment for a certain period of time. It becomes feasible.
Specifically, for example, for each of a stereoscopic image display device obtained through an annealing process in which heat treatment is performed at 70 ° C. for 24 hours and a stereoscopic image display apparatus obtained without undergoing the annealing process, after completion An experiment was performed in which the number of bubbles visually recognized was counted in an area of 14 cm × 35 cm in the panel for 48 hours in an environment of 70 ° C. As a result, it was found that the number of bubbles was 61 for those not subjected to the annealing process, whereas the number of bubbles was 2 for those subjected to the annealing process.
That is, through the annealing process, it is possible to drastically reduce the generation of bubbles from the phase difference element 3 that causes product defects.

[2-2. Light shielding layer forming step]
As described above, the stereoscopic image display device includes the light shielding layer 4. Therefore, in the manufacturing process of the stereoscopic image display device, a light shielding layer forming step for forming the light shielding layer 4 is performed.

Here, the case where the light shielding layer 4 in the first schematic configuration example described above is formed using transfer of the light shielding layer 4 will be described as an example.
FIG. 3 is an explanatory view showing a specific example of the outline of the light shielding layer forming step.

  In the light shielding layer forming step, first, a polarizing plate 2 is prepared as shown in FIG. For example, in the case where the polarizing plate 2 is assembled and supplied integrally with the image display panel 1, it is possible to separate the polarizing plate 2 from the image display panel 1 so that the polarizing plate 2 is in a single state. And if the polarizing plate 2 is prepared, the 1st bonding agent layer 5 will be formed by the uniform thickness on the formation surface (surface on the image display panel 1 side) of the light shielding layer 4 in the polarizing plate 2.

  On the other hand, the light shielding layer 4 is formed on the surface of the base material sheet 4a made of, for example, a TAC film via an adhesive layer 4b for releasably fixing the light shielding layer 4 to the surface. Shall be kept. At this time, the pressure-sensitive adhesive layer 4 b is set so that the pressure-sensitive adhesive force is smaller than the pressure-sensitive adhesive force in the first bonding agent layer 5. Note that a specific method for forming the light shielding layer 4 may be performed using a known technique such as a photolithography technique, and thus the description thereof is omitted here.

  If the 1st bonding agent layer 5 is formed on the polarizing plate 2 and the light shielding layer 4 is formed on the base material sheet 4a via the adhesive layer 4b, the said light shielding layer 4 will become the 1st bonding agent layer 5 after that. In the faced state, they are bonded together. At this time, pressurization from both sides is performed so that the light shielding layer 4 enters the first bonding agent layer 5.

  And after bonding these together, as shown in FIG.3 (b), peeling of the base material sheet 4a is performed. At this time, the pressure-sensitive adhesive layer 4 b disposed on the base material sheet 4 a is set to have a lower adhesive force than the first bonding agent layer 5. Therefore, when the base sheet 4a is peeled off, the light shielding layer 4 formed on the base sheet 4a is transferred from the base sheet 4a to the polarizing plate 2 due to the difference in the adhesive strength. Is done. That is, the light shielding layer 4 is fixed on the surface of the polarizing plate 2 using the first bonding agent layer 5.

  By thus transferring the light shielding layer 4 to the polarizing plate 2 side, the light shielding layer 4 is projected on the surface of the polarizing plate 2. And the location which becomes a light transmissive area | region without the light shielding layer 4 protruding is in the state filled with the 1st bonding agent layer 5 so that the concave-shaped part formed with the said light shielding layer 4 may be filled. . It should be noted that the first bonding agent layer 5 is not interposed on the top surface of the light shielding layer 4 protruding on the surface of the polarizing plate 2 (the top surface of the convex portion formed by the light shielding layer 4). In addition, with the peeling of the base sheet 4a, the pressure-sensitive adhesive layer 4b is also peeled off and does not remain.

  If the light shielding layer formation process of the above procedures is implemented, the light shielding layer 4 formed on the base material sheet 4a so as to be peelable is transferred from the base material sheet 4a, and is applied onto the surface of the polarizing plate 2. The light shielding layer 4 is projected. Therefore, compared with the case where the light shielding layer 4 is directly formed on the surface of the polarizing plate 2, the formation of the light shielding layer 4 can be facilitated.

  Here, the case where the light shielding layer 4 is formed using transfer from the base material sheet 4a is taken as an example, but the light shielding layer forming step is performed without using such transfer of the light shielding layer 4. It is also possible to do. For example, in the case of the second schematic configuration example described above, after the light shielding layer 4 is formed on the base sheet 4a, these are directly applied to the surface of the polarizing plate 2 via the second bonding agent layer 7. The light shielding layer 4 may be formed on the surface of the polarizing plate 2 by pasting. Further, the light shielding layer 4 may be directly projected on the surface of the polarizing plate 2 using a known technique such as a photolithography technique without using the base sheet 4a.

  Further, here, in the light shielding layer forming step, the case where the light shielding layer 4 is formed on the polarizing plate 2 in a single state using transfer from the base material sheet 4a is taken as an example. The transfer target of the light shielding layer 4 from above 4a is not limited to the polarizing plate 2 in a single state. For example, it is conceivable that the polarizing plate 2 in a state where the retardation element 3 is bonded with the second bonding agent layer 7 interposed therebetween is used as a transfer target of the light shielding layer 4 from the substrate sheet 4a. In other words, either the light shielding layer forming step or the second bonding step described later may be performed first.

[2-3. Positioning process]
When configuring a stereoscopic image display device, it is necessary to accurately position the image display panel 1, the phase difference element 3, and the light shielding layer 4 relative to each other.
For example, the position between the image display panel 1 and the phase difference element 3 is not accurately positioned, and the position of the right-eye image display unit 3a with respect to the right-eye image, the position of the left-eye image display unit 3b with respect to the left-eye image, etc. If this occurs, problems such as an unclear image captured by the viewer and a loss of stereoscopic effect may occur. Specifically, for example, when displaying a 40-inch class HD signal (high-definition signal), the vertical direction of one pixel line is an extremely fine line of about 500 μm, so the allowable range of positional deviation is less than 5%. In this case, it is necessary to perform positioning at the 25 μm level.
Further, for example, the phase difference element 3 and the light shielding layer 4 are not accurately positioned, and the arrangement position of the light shielding layer 4 is shifted from the boundary portion between the right-eye image display unit 3a and the left-eye image display unit 3b. This is because the occurrence of the crosstalk phenomenon cannot be prevented, or the luminance of the display image is lowered due to the decrease of the passing light.
For these reasons, in manufacturing a stereoscopic image display device, prior to bonding between the image display panel 1, the phase difference element 3, and the light shielding layer 4, a positioning step for performing planar positioning on these is performed. carry out.

[2-3-1. First example of positioning process]
FIG. 4 is an explanatory diagram showing a first example of an outline of the positioning process.
In the illustrated example, the image display panel 1 and the laminated body including the light shielding layer 4, the second bonding agent layer 7, the polarizing plate 2, the retardation element 3, the antireflection film 8, and the bonding agent layer 7 are planar. This shows a case of performing simple alignment. However, it is conceivable that the planar alignment is applied in the same manner not only in the case of the illustrated example but also when the light shielding layer 4 and the polarizing plate 2 are bonded to the retardation element 3.
When performing the planar alignment shown in the figure, first, the image display panel 1 is supported on the upper pedestal 11 of the alignment apparatus, and the light shielding layer 4 and the retardation element are supported on the lower pedestal 12 of the alignment apparatus. A laminated body such as 3 is supported, and these are opposed to each other. The support by the upper pedestal 11 and the lower pedestal 12 may be performed using a known technique such as vacuum suction. In addition, at least one of the upper pedestal 11 and the lower pedestal 12 is assumed to have a structure that can slide in the front-rear and left-right directions or the up-down direction in the drawing.
In the alignment apparatus, an imaging device 13 such as an image processing camera for position detection is arranged on one side of the upper pedestal 11 and the lower pedestal 12. Further, a light source 14 for irradiating light is disposed on the side facing the imaging device 13 with the upper pedestal 11 and the lower pedestal 12 interposed therebetween. The light source 14 is provided with a polarizing plate 15 that realizes a polarization state corresponding to either the right-eye image display unit 3 a or the left-eye image display unit 3 b in the phase difference element 3.
Note that the alignment device employs a bifocal depth switching mechanism, so that the alignment can be performed optimally while maintaining a gap with respect to the marking line added to the image from the imaging device 13. A mechanism may be installed.

  In the alignment apparatus having such a configuration, for example, planar alignment for the phase difference element 3, more specifically, when the light shielding layer 4 and the polarizing plate 2 are bonded to the phase difference element 3. In planar alignment, the irradiation light from the light source 14 is caused to reach the phase difference element 3 via the polarizing plate 15 disposed between the light source 14 and the laminate. Then, the light transmitted through the phase difference element 3 is imaged by the imaging device 13. At this time, the irradiation light from the light source 14 is polarized by the polarizing plate 15. Therefore, the transmitted light reaches the imaging device 13 for either the right-eye image display unit 3a or the left-eye image display unit 3b, but the other is shielded without transmitting the irradiation light from the light source 14. Therefore, according to the imaging result of the imaging device 13, the boundary between the right-eye image display unit 3 a and the left-eye image display unit 3 b in the phase difference element 3 is clearly recognized.

By the way, when the liquid crystal panel constituting the image display panel 1 is of a so-called normally black type, the liquid crystal can be applied even when illumination light having a light quantity of about the backlight is applied from one side in a voltage non-applied state. It is difficult to achieve light transmission through the panel. In addition, it is not realistic to apply a voltage to the liquid crystal panel for alignment.
Therefore, in the alignment apparatus, planar alignment of the image display panel 1 is performed, and more specifically, when a laminate such as the light shielding layer 4 and the retardation element 3 is bonded to the image display panel 1. In the planar alignment, even if the normally black type liquid crystal panel is not applied with a voltage from the light source 14, that is, even when the light transmittance in the liquid crystal panel is minimized, the liquid crystal panel is Irradiation light with a transmitted light amount is emitted. Specifically, it is conceivable to emit irradiation light exceeding, for example, 30,000 lux as the minimum light amount. However, it is desirable to suppress the maximum light amount to such an extent that it does not adversely affect liquid crystal molecules in the liquid crystal panel.
By emitting such an amount of irradiation light from the light source 14, even if the liquid crystal panel is of a normally black type, light is transmitted through the liquid crystal panel without applying voltage to the liquid crystal panel, The imaging device 13 is reached. Therefore, according to the imaging result of the imaging device 13, for example, it is possible to distinguish between a portion through which light passes, such as a pixel region, and a portion covered with a light-shielding film, such as a wiring region. The planar position of the panel 1 is clearly recognized.

  According to the positioning process as described above, the alignment accuracy between the image display panel 1 and the laminated body such as the phase difference element 3 is about 25 μm compared with the conventional one in which variation of 50 to 60 μm has occurred. It becomes feasible to improve it.

[2-3-2. Second example of positioning process]
FIG. 5 is an explanatory view showing a second example of the outline of the positioning step.
In the illustrated example, prior to the light shielding layer forming step, the light shielding layer 4 formed to be peelable on the base sheet 4a, the polarizing plate 2 bonded to each other with the second bonding agent layer 7 interposed therebetween, and the retardation The case where planar alignment is performed with the element 3 is shown.

As already described, it is necessary to accurately perform relative positioning between the phase difference element 3 and the light shielding layer 4. Specifically, the light-shielding layer 4 has a very fine line shape in which the vertical direction of one pixel line is about 500 μm, but is generally required to have an accuracy in which the allowable range of positional deviation is less than 10%.
On the other hand, the base sheet 4a formed so that the light shielding layer 4 can be peeled is generally low in transparency for the convenience of forming the light shielding layer 4 so as to be peelable.
Therefore, when the polarizing plate 2 and the retardation element 3 are bonded to each other and further formed by transferring the light shielding layer 4 thereon, even if natural light is transmitted through the polarizing plate 2 and the retardation element 3, The phase difference element 3 may be insufficient at the boundary between the right-eye image display unit 3a and the left-eye image display unit 3b, making it difficult to perform bonding with high required positional accuracy.

Therefore, in the second example of the positioning step described here, as shown in FIG. 5, first, the base sheet 4a on which the light shielding layer 4 is formed so as to be peelable is supported on the upper base 11 of the alignment apparatus. Further, the laminated body of the polarizing plate 2 and the retardation element 3 is supported on the lower base 12 of the alignment apparatus. And these are made to oppose each other in the state which maintained the fine clearance gap which does not adhere between upper and lower sides. The support by the upper pedestal 11 and the lower pedestal 12 may be performed using a known technique such as vacuum suction. In addition, at least one of the upper pedestal 11 and the lower pedestal 12 is assumed to have a structure that can slide in the front-rear and left-right directions or the up-down direction in the drawing.
In the alignment device, an imaging device 13 such as an image processing camera for position detection is arranged on the lower pedestal 12 side. On the other hand, a light source 14 for irradiating light is disposed on the side facing the imaging device 13 with the lower pedestal 12 and the upper pedestal 11 interposed therebetween. A polarizing plate 15 that realizes a polarization state corresponding to either the right-eye image display unit 3 a or the left-eye image display unit 3 b in the phase difference element 3 is disposed between the lower pedestal 12 and the imaging device 13. It is installed.
Note that the alignment device employs a bifocal depth switching mechanism, so that the alignment can be performed optimally while maintaining a gap with respect to the marking line added to the image from the imaging device 13. Assume that a mechanism is installed.

  In the alignment apparatus having such a configuration, prior to the light shielding layer forming step, in the planar alignment between the light shielding layer 4 on the base sheet 4a and the polarizing plate 2 and the retardation element 3 bonded to each other, The irradiation light from the light source 14 is sequentially transmitted through the base sheet 4 a and the phase difference element 3, and then is transmitted to the image pickup apparatus 13 via the polarizing plate 15 disposed on the image pickup apparatus 13 side of the phase difference element 3. To reach. The light transmitted through the polarizing plate 15 is imaged by the imaging device 13.

At this time, the irradiation light from the light source 14 permeate | transmits the base material sheet 4a with low transparency. Therefore, a diffraction phenomenon of transmitted light occurs due to refraction or irregular reflection of light during the transmission. That is, even if the light shielding layer 4 is formed on the imaging device 13 side of the base sheet 4a, the transmitted light wraps around to the back side of the light shielding layer 4, so that the transmitted light is not shielded by the light shielding layer 4 and has a phase difference. The element 3 is reached.
At this time, the irradiation light from the light source 14 is polarized by the polarizing plate 15. Therefore, the transmitted light reaches the imaging device 13 for either one of the right-eye image display unit 3a or the left-eye image display unit 3b in the phase difference element 3, but the transmitted light is shielded for the other.
As described above, the polarizing plate 15 switches between transmission and blocking of light in each of the right-eye image display unit 3a and the left-eye image display unit 3b. If it is only for this switching, it is also conceivable that the polarizing plate 15 is disposed on the light source 14 side as in the case of the first example described above. However, when the polarizing plate 15 is disposed on the light source 14 side, the polarization state of the irradiation light from the light source 14 is adjusted by transmitting through the polarizing plate 15, and the diffraction phenomenon of the light transmitted through the base sheet 4 a. May be difficult to occur. Therefore, it is desirable that the polarizing plate 15 is disposed not on the light source 14 side but on the imaging device 13 side.

The imaging device 13 to which the light transmitted through the base sheet 4a, the phase difference element 3, and the polarizing plate 15 arrives employs a bifocal depth switching mechanism.
Therefore, when the depth of focus is adjusted to the phase difference element 3, the imaging result of the imaging device 13 is obtained by focusing on the phase difference element 3 and passing through the polarizing plate 15. The boundary between the right-eye image display unit 3a and the left-eye image display unit 3b becomes clear.
On the other hand, when the depth of focus is adjusted to the light shielding layer 4, the imaging result of the imaging device 13 is obtained through focusing on the light shielding layer 4 and generation of the light diffraction phenomenon. The position of the edge of 4 becomes clear.

These imaging results are stored and held in a storage device included in the alignment device or a storage device accessible by the alignment device.
Therefore, in the alignment device, based on the memory holding result, that is, the imaging result when the focus of the imaging device 13 is adjusted to the light shielding layer 4 and the imaging result when the focus is adjusted to the phase difference element 3, It is possible to perform alignment with the phase difference element 3. Specifically, the upper part of the phase difference element 3 is arranged such that the boundary between the right-eye image display unit 3a and the left-eye image display unit 3b and the central part of the line width of the light shielding layer 4 are located at positions that match each other. It is conceivable to move at least one of the base 11 and the lower base 12.

  According to the positioning process as described above, the base material sheet 4a on which the light shielding layer 4 is formed is disposed on the light source 14 side, and the phase difference element 3 is disposed on the imaging device 13 side. Therefore, planar alignment between the phase difference element 3 and the light shielding layer 4 can be performed without being affected by the base sheet 4a having low transparency. Accordingly, for example, when an optical system camera having an enlargement capability of about 60 times is used as the imaging device 13, the optical system camera is used while using bifocal depth switching with respect to the phase difference element 3 and the light shielding layer 4. It is possible to perform highly accurate alignment in a short time with respect to the marking line added to. Specifically, in the accuracy of alignment, for example, a conventional variation of −50 to +80 μm can be compressed to about −40 to +40 μm, which is halved. This makes it possible to improve the positioning accuracy of the planar alignment between the phase difference element 3 and the light shielding layer 4.

[2-4. Bonding process]
After performing the planar alignment between the image display panel 1, the phase difference element 3, and the polarizing plate 2 on which the light shielding layer 4 is formed, the alignment state is subsequently maintained, A pasting step of pasting them together is performed.
In the bonding step, the first bonding step of bonding the image display panel 1 and the polarizing plate 2 on which the light shielding layer 4 is formed with the first bonding agent layer 5 interposed therebetween, and the second bonding agent layer 7 There is a second bonding step in which the polarizing plate 2 on which the light shielding layer 4 is formed and the retardation element 3 are bonded to each other.
Either of the first bonding step and the second bonding step may be performed first, but here the case of performing the first bonding step after performing the second bonding step is taken as an example. The following description will be given.

[2-4-1. Second bonding step]
The polarizing plate 2 on which the light shielding layer 4 is formed and the retardation element 3 are bonded together by interposing the second bonding agent layer 7 therebetween. At this time, the second bonding agent layer 7 is between the non-formation surface side of the light shielding layer 4 in the polarizing plate 2 and the formation surface side of the right-eye image display unit 3a and the left-eye image display unit 3b in the retardation element 3. In this case, it is interposed in the entire area.
The second bonding agent layer 7 is made of a transparent gel-like acrylic adhesive and has a layer thickness of 25 to 100 μm, just as in the case of the first bonding agent layer 5 for the reason described later. It is conceivable to use one having a hardness of the adhesive material of greater than 0 and 350,000 μN or less, and a holding force after bonding at 40 ° C. of 8 to 20 N / 20 mm.
Alternatively, as the second bonding agent layer 7, the storage rigidity at 30 to 70 ° C. is in the range of greater than 0 to 70,000 Pa or less, just as in the case of the first bonding agent layer 5, for the reasons described later. It is conceivable to use a material whose rigidity is in the range of more than 0 and 20000 Pa or less and whose creep characteristics are 0.3 mm or less.
In the second bonding step, the antireflection film 8 is also bonded to the retardation element 3 via the third bonding agent layer 9.

[2-4-2. First bonding step]
After the laminated body composed of the light shielding layer 4, the polarizing plate 2, the retardation element 3, and the like is formed by the second bonding step described above, the bonding of the laminated body and the image display panel 1 is performed using the first bonding agent. This is done by interposing the layer 5.
However, in the case of the first schematic configuration example described above, the first bonding agent layer 5 includes the light shielding layer 4 between the image display panel 1 and the light shielding layer 4 formation surface side of the polarizing plate 2. It is made to intervene in a place except between the top surface and the image display panel 1. Specifically, the portion except the top surface of the light shielding layer 4, that is, the portion where the light shielding layer 4 is not projected on the surface of the polarizing plate 2 and serves as a light transmission region is formed by the light shielding layer 4. The first bonding agent layer 5 is filled so as to fill the recessed portion to be formed, and the first bonding agent layer 5 is interposed.
On the other hand, the first bonding agent layer 5 is not interposed between the top surface of the light shielding layer 4. Thereby, after bonding the image display panel 1 and a laminate such as the polarizing plate 2, the first bonding agent layer 5 is not filled between the image display panel 1 and the top surface of the light shielding layer 4. An air layer 6 is formed.

As the first bonding agent layer 5 that is interposed in a portion other than the space between the top surface of the light shielding layer 4, it is desirable to use a material that satisfies the conditions described below.
The first bonding agent layer 5 is present at a location that becomes a light transmission region. Therefore, the first bonding agent layer 5 should not adversely affect the optical characteristics between the image display panel 1 and the polarizing plate 2 after bonding. Therefore, as a material for forming the first bonding agent layer 5, a transparent gel-like acrylic pressure-sensitive adhesive having light transmittance is used.
Further, if the first bonding agent layer 5 is too thin, it is difficult to ensure the uniformity of the layer. Furthermore, for example, when waviness or the like occurs on the bonding surface of the image display panel 1 and the planar uniformity is poor, it is difficult to absorb this. Moreover, considering that the light shielding layer 4 is formed by transfer in the light shielding layer forming step, for example, it is desirable that the layer thickness is at least greater than the protruding height of the light shielding layer 4. On the other hand, if the thickness of the first bonding agent layer 5 is too thick, there is a possibility that an adverse effect on optical characteristics such as a decrease in light transmittance may occur, and there is a high possibility that foreign substances such as bubbles will be mixed. For these reasons, the first bonding agent layer 5 is formed to have a layer thickness of 25 to 100 μm.
Furthermore, the first bonding agent layer 5 is formed by the function as a buffer material between the image display panel 1 and the polarizing plate 2 or the light shielding layer 4 when the hardness of the pressure-sensitive adhesive as the forming material is too high. Since the filling function etc. which fill a recessed shape part is inhibited, it is not preferable.
Moreover, if the 1st bonding agent layer 5 has too small the retention strength after bonding, it will become difficult to maintain the planar alignment state between the image display panel 1 and a polarizing plate. On the other hand, if the holding force after pasting is too large, it is not preferable because, for example, when a problem occurs, it is impossible to peel off the pasting portion by the first bonding agent layer 5 and to perform pasting again.
From these things, the 1st bonding agent layer 5 shall set the hardness of the adhesive which is a forming material, and the retention strength after bonding as described below.

FIG. 6 is an explanatory diagram showing a specific example of the relationship between the pressure-sensitive adhesive hardness and the pressure-sensitive adhesive layer holding force.
FIG. 6 (a) shows the result of a comparative examination of the pressure-sensitive adhesive hardness and the pressure-sensitive adhesive layer holding power for several types of pressure-sensitive adhesive layers having a thickness of 100 μm.
As for the adhesive hardness, as shown in FIG. 6B, the rebound strength at the time of compression (for example, when the 100 μm adhesive 21 sinks 50 μm) is used as an index.
Moreover, as shown in FIG.6 (c), the adhesive strength (adhesive strength) of the adhesive is based on the peel strength of the adhesive 23 having a width of 20 mm with respect to the glass material 22.
As shown in FIG. 6 (a), the pressure-sensitive adhesive hardness and the pressure-sensitive adhesive layer holding force were measured and compared under such conditions, and as a result, the pressure-sensitive adhesive hardness was 350,000 μN or less and held after bonding at 40 ° C. It has been found that when the force is 8 to 20 N / 20 mm, the entire bonding surface can be maintained in an accurately positioned state without causing bubbles or peeling and with no problem in appearance.
Accordingly, the first bonding agent layer 5 is set so that the hardness of the pressure-sensitive adhesive as a forming material is in the range of greater than 0 to 350,000 μN and the holding force after bonding at 40 ° C. is 8 to 20 N / 20 mm. It shall be.

Further, as the first bonding agent layer 5, it is conceivable to use a material that satisfies the following conditions in addition to the above-described conditions or separately from the above-mentioned conditions (not the above-mentioned conditions).
Since the 1st bonding agent layer 5 exists in the location used as a light transmissive area | region, the transparent gel-like acrylic adhesive which has a light transmittance is used as the formation material.
The first bonding agent layer 5 is formed by the function as a buffer material between the image display panel 1 and the polarizing plate 2 or the light shielding layer 4 when the hardness of the pressure-sensitive adhesive as a forming material is too high. Since the filling function etc. which fill a recessed shape part is inhibited, it is not preferable. On the other hand, it is necessary for the pressure-sensitive adhesive to have a low elasticity and a high viscosity so as not to disturb the filling function and the like.
Furthermore, when the 1st bonding agent layer 5 has too small the retention strength after bonding, it will become difficult to maintain the planar alignment state between the image display panel 1 and a polarizing plate. In particular, considering the case of being placed in a high temperature environment as described above for a certain period of time, it is difficult to maintain the alignment state unless the creep characteristics are small. On the other hand, if the holding force after bonding is too large, it is not preferable because, for example, at the time of a failure, it is impossible to peel off the bonding portion by the first bonding agent layer 5 and to bond again.
From these facts, it is assumed that the first bonding agent layer 5 has the elasticity, viscosity, and creep characteristics of the pressure-sensitive adhesive as the forming material set as described below.

7 and 8 are explanatory diagrams showing specific examples of adhesive elasticity, viscosity, and creep characteristics.
FIG. 7 shows the result of comparative examination of adhesive elasticity and adhesive viscosity for several types of adhesive layers.
Moreover, Fig.8 (a) has shown the result of having investigated creep force about the adhesive layer. In addition, as shown in FIG. 8B, the creep force (adhesive strength) of the pressure-sensitive adhesive is based on the amount of deviation (mm) after 1 hour with a load of 1 kg at a temperature of 80 ° C. Yes.
As shown in FIGS. 7 and 8, as a result of actually measuring the pressure-sensitive adhesive elasticity, viscosity, and creep characteristics under such conditions and comparing them, the storage rigidity (corresponding to elasticity) at 30 to 70 ° C. is larger than 0. It is 70000 Pa or less, the loss rigidity (corresponding to viscosity) is greater than 0 and 20000 Pa or less, and the creep property is also 0.3 mm or less. However, it has been found that the gap between these areas can be filled and the position can be maintained accurately without any problem in appearance.
Therefore, the first bonding agent layer 5 has a storage rigidity of the pressure-sensitive adhesive as a forming material at 30 to 70 ° C. in the range of greater than 0 to 70000 Pa and a loss rigidity of greater than 0 to 20000 Pa. The creep characteristics are set to be 0.3 mm or less by satisfying these conditions.

Here, the case corresponding to the first schematic configuration example has been described as an example, but the case corresponding to the second schematic configuration example can be performed in exactly the same manner except for the intervening portion of the first bonding agent layer 5. Good.
Moreover, even if it is a case of any structural example, it is not an adhesive as mentioned above as the 1st bonding agent layer 5 used at a 1st bonding process, or the 2nd bonding agent layer 7 used at a 2nd bonding process. It is also conceivable to use other pressure-sensitive adhesives and adhesives.

[2-4-3. Pressure bonding process in the bonding process]
By the way, when bonding about the image display panel 1, the polarizing plate 2, the phase difference element 3, the light shielding layer 4, etc. in the 1st bonding process or the 2nd bonding process, panel size becomes large. In addition, there is a high possibility that a minute bubble or the like is involved during the bonding. In addition, since it is difficult to maintain high surface accuracy or the like for the top surface of the image display panel 1 or the phase difference element 3 or the light shielding layer 4, waviness or the like is generated on the bonding surface between them, and the surface is uniform. There is a high possibility that the property will be poor, and there is a possibility that a local gap may be formed, and the adhesion and the separation distance between them may not be uniform.
For these reasons, when the image display panel 1, the polarizing plate 2, the retardation element 3, the light shielding layer 4 and the like are bonded, the bonding is performed while applying pressure using a bonding roller.

FIG. 9 is an explanatory diagram showing a specific example of pressure bonding using a bonding roller.
In addition, in the example of a figure, although the crimping | compression-bonding process in a 1st bonding process is mentioned as an example, it is also possible to apply in the same way also about a 2nd bonding process.

  As shown to Fig.9 (a), when bonding the polarizing plate 2 with which the light shielding layer 4 was formed, the phase difference element 3, etc. with respect to the image display panel 1 in a 1st bonding process, these are performed. In a state where the first bonding agent layer 5 is interposed between the two layers, the lamination is pressed from above and below in the laminating direction from one end side to the other end side of these laminates (see arrows in the figure). The roller 31 is made to travel and bonding about the laminate is performed.

At this time, the laminating roller 31 pressurizes with a force belonging to a predetermined range and runs at a speed belonging to the predetermined range.
Specifically, as shown in FIG. 9B, pressurization is performed with the applied pressure belonging to the optimum condition area, and the vehicle is driven at a speed belonging to the optimum condition area. This is because if the applied pressure is low or the speed is too high, the possibility of entraining bubbles or the like increases.
The optimum condition area can be derived through empirical rules such as experiments. In the illustrated example, the relationship between the pressing force of the laminating roller 31 and the traveling speed when the vertical position (clearance) of the support 32 described later is 0.4 mm is shown. However, the vertical position needs to be arbitrarily adjusted to the thickness, size, etc. of the light shielding layer 4, the polarizing plate 2, the phase difference element 3, etc. to be bonded, and accordingly, the relationship between the applied pressure and the traveling speed is also natural. Will be different.

Moreover, in the pressure bonding using the roller 31 for bonding, the light shielding layer 4 in the other end side of the laminated body used as the travel destination of the roller 31 for bonding rather than the bonding position by the roller 31 for bonding. The edge position of the laminated body including the polarizing plate 2 is held so that the polarizing plate 2 on which is formed has a gap with respect to the image display panel 1.
Specifically, as shown in FIG. 9A, the edge position of the laminate including the polarizing plate 2 is supported by the support 32, thereby the image display panel 1 and the laminate including the polarizing plate 2. There is a gap between them. Then, the edge position of the laminate including the polarizing plate 2 is moved in conjunction with the running state of the laminating roller 31. That is, as the laminating roller 31 approaches the support 32, the position of the support 32 is moved so that the gap between the image display panel 1 and the laminate including the polarizing plate 2 is reduced.
In addition, about the driving | running | working of the roller 31 for bonding, and the mechanism etc. which interlock | cooperate the support element 32 with respect to this, since what is necessary is just to implement | achieve using a well-known technique, the detailed description is abbreviate | omitted here.

If pressure bonding using such a bonding roller 31 is performed, the vertical position of the support 32 holding one end of the laminate including the polarizing plate 2 and the traveling speed of the bonding roller 31 are interlocked. Then, the laminating body is sequentially pressed by the laminating roller 31 while warping, and the laminating is performed. Therefore, since the escape path for air bubbles and the like is always secured on the side where the laminating roller 31 is run, the image display panel 1 can be used while minimizing the entry of fine dust and biting bubbles. Can be bonded to the laminate.
In addition, the pressure applied by the laminating roller 31 and the traveling speed are also optimized in order to suppress entrainment of bubbles and the like.

  Therefore, about the laminated body obtained as a result of the above-mentioned pressure bonding, even if there are inferior flatness parts due to swells etc. in each component, it is bonded under appropriate and uniform pressure conditions. , Local gaps do not occur, and adhesion, separation distance, etc. are not uniform. Further, even when the panel size is increased, it is possible to prevent entrainment of bubbles and the like.

<3. Effect in this embodiment>
Next, effects of the stereoscopic image display device obtained by the manufacturing method as described above will be described.
FIGS. 10-13 is explanatory drawing which shows the outline | summary of the effect of the stereo image display apparatus based on this invention concretely.

As shown in FIG. 10A, in the stereoscopic image display device having the configuration described in the present embodiment, the light shielding layer 4 is disposed on the image display panel 1 side with respect to the polarizing plate 2. For comparison with this, FIG. 10B shows a conventional component, that is, the light shielding layer 4 is formed on the surface of the phase difference element 3 such that the light shielding layer 4 is directly formed on the polarizing plate 2. The configuration located on the image output surface side (the side far from the image display panel 1) is shown.
Comparing these, it is clear that the three-dimensional image display device of the present embodiment has the light shielding layer 4 in a position closer to the image display panel 1 than the conventional component. Therefore, in the stereoscopic image display device according to the present embodiment, if the occurrence of the crosstalk phenomenon is prevented for the same viewing angle, the formation width of the light shielding layer 4 may be smaller than that of the conventional configuration product. That is, if θ1 = θ2 in the figure, the relationship of W1 <W2 is established.

Here, consider a case where the crosstalk rate is 7%.
The crosstalk rate is generally defined as shown in FIG. Note that the crosstalk rate of 7% corresponds to a limit level that most viewers can see as a stereoscopic image without feeling uncomfortable and not feeling tired.

As described above, when the light shielding layer 4 is present at a position closer to the image display panel 1 than the polarizing plate 2, the width of the light shielding layer 4 can be made smaller than that of the conventional component. Therefore, even when the crosstalk phenomenon (crosstalk ratio is 7%) is kept at the same level as that of the conventional component, the luminance (aperture ratio) specified by the formation area of the light shielding layer 4 is It is possible to improve from 65% to 70% of the components.
Specifically, as shown in FIG. 12, it has been found that the screen brightness is improved as compared with the conventional components. The relationship between the stereoscopic viewing angle and the screen brightness is linear data as shown in the example, but it has been confirmed by experiments that it contributes to the improvement that does not hinder the 40-inch screen. Yes.

  If the light shielding layer 4 is located closer to the image display panel 1 than the polarizing plate 2, the viewing distance and the formation pitch (pixel pitch ratio) of the light shielding layer 4 are as shown in FIG. I found out that

  As described above, in the stereoscopic image display device according to the present embodiment, it is possible to reduce the formation width of the light shielding layer 4 as compared with the conventional component in which the light shielding layer 4 is located on the image output surface side of the polarizing plate 2. It becomes. Therefore, it is possible to suppress the decrease in luminance of the display image as much as possible while preventing the occurrence of the crosstalk phenomenon. In other words, it is possible to cope with an event having a trade-off relationship (prevention of crosstalk) such as prevention of occurrence of a crosstalk phenomenon and prevention of luminance reduction of a display image, as compared with a conventional product.

  In the above-described embodiments, preferred specific examples of the present invention have been described. However, the present invention is not limited to the contents, and can be appropriately changed without departing from the gist thereof. .

  DESCRIPTION OF SYMBOLS 1 ... Image display panel, 2 ... Polarizing plate, 3 ... Phase difference element, 3a ... Right-eye image display part, 3b ... Left-eye image display part, 3c ... Support base material, 4 ... Light shielding layer, 4a ... Base material sheet, DESCRIPTION OF SYMBOLS 5 ... 1st adhesive agent layer, 6 ... Air layer, 7 ... 2nd adhesive agent layer, 13 ... Imaging device, 14 ... Light source, 15 ... Polarizing plate, 31 ... Rolling roller, 32 ... Supporter

Claims (19)

An image display panel that displays a right-eye image and a left-eye image mixed regularly in a plane;
A right-eye image display unit corresponding to the right-eye image disposed on the image output surface side with respect to the image display panel and polarizing the right-eye image and the left-eye image in different polarization states; A phase difference element having a left-eye image display unit corresponding to the left-eye image;
A polarizing plate disposed between the image display panel and the retardation element;
A light shielding layer disposed between the image display panel and the polarizing plate so as to correspond to a region portion including a boundary between the right-eye image display unit and the left-eye image display unit in the phase difference element; A stereoscopic image display device comprising: The light shielding layer is formed on a surface of the polarizing plate on the image display panel side, and these are bonded to each other between the image display panel and the light shielding layer forming surface side of the polarizing plate. The stereoscopic image display device according to claim 1, wherein a first bonding agent layer is interposed. The first bonding agent layer is interposed between the image forming panel side of the light shielding layer and the image display panel in the polarizing plate except between the top surface of the light shielding layer and the image display panel. 3. The stereoscopic image display device according to 2. 4. The stereoscopic image display device according to claim 1, further comprising a second bonding agent layer that is interposed between the polarizing plate and the retardation element and bonds them together. The first bonding agent layer and the second bonding agent layer are made of a transparent gel-like acrylic pressure-sensitive adhesive material, have a layer thickness of 25 to 100 μm, and have a hardness of the pressure-sensitive adhesive material greater than 0 and 350,000 μN or less. The stereoscopic image display device according to claim 4, wherein the holding force after bonding at 40 ° C. is 8 to 20 N / 20 mm. The first bonding agent layer and the second bonding agent layer are made of a transparent gel-like acrylic pressure-sensitive adhesive material, and the storage rigidity at 30 to 70 ° C. is in the range from 0 to 70000 Pa, and the loss rigidity is The stereoscopic image display apparatus according to claim 4, wherein the range is greater than 0 and less than or equal to 20000 Pa. A polarizing plate arranged so as to cover the image output surface side of the image display panel that displays the right-eye image and the left-eye image mixed regularly in the plane, and the right-eye image display corresponding to the right-eye image And a left-eye image display unit corresponding to the left-eye image, and between the right-eye image display unit and the left-eye image display unit configured to realize different polarization states. A second bonding step in which the polarizing plate and the retardation element are bonded to each other with a second bonding agent layer interposed therebetween,
Prior to the second bonding step, only the region portion including the boundary between the right-eye image display unit and the left-eye image display unit in the retardation element on the surface of the polarizing plate on the image display panel side. A light shielding layer forming step of projecting the light shielding layer so as to correspond to
After the light shielding layer forming step, a first bonding agent layer is interposed between the image display panel and the light shielding layer forming surface side of the polarizing plate, and the image display panel, the polarizing plate, and the light shielding are provided. The manufacturing method of the three-dimensional image display apparatus containing the 1st bonding process of bonding a layer mutually. The said light shielding layer formation process transfers the said light shielding layer formed on the base material so that peeling is possible from the said base material, and projects the said light shielding layer on the surface of the said polarizing plate. Manufacturing method of the stereoscopic image display apparatus. In the first bonding step, the first bonding agent layer is formed between the image display panel and the formation surface side of the light shielding layer in the polarizing plate except between the top surface of the light shielding layer and the image display panel. The manufacturing method of the three-dimensional image display apparatus of Claim 7. In the first bonding step, the first bonding agent layer is made of a transparent gel-like acrylic pressure-sensitive adhesive material, has a layer thickness of 25 to 100 μm, and the pressure-sensitive adhesive material has a hardness of more than 0 and 350,000 μN or less. The manufacturing method of the three-dimensional image display apparatus of Claim 7 which uses the thing which is in a range and whose holding power after bonding in 40 degreeC is 8-20N / 20mm. In the first bonding step, the first bonding agent layer is made of a transparent gel-like acrylic adhesive, and the storage rigidity at 30 to 70 ° C. is in the range of more than 0 to 70000 Pa or less, and the loss rigidity is The manufacturing method of the three-dimensional image display apparatus of Claim 7 which uses what is in the range of more than 0 and 20000 Pa or less. In the first bonding step,
From one end side to the other end side of the laminate composed of the image display panel, the first bonding agent layer, the light shielding layer, and the polarizing plate, the laminate is applied with a force within a predetermined range from above and below in the stacking direction. The laminating roller that is pressed is run at a speed belonging to a predetermined range, and the laminating body is bonded,
At the time of the bonding, an edge on the other end side of the polarizing plate so that the polarizing plate and the light shielding layer have a gap with respect to the image display panel on the other end side with respect to the bonding roller. The manufacturing method of the three-dimensional image display apparatus of Claim 10 or 11 which moves the position of the said edge in conjunction with the driving | running | working state of the said roller for pasting. In the second bonding step, the second bonding agent layer is made of a transparent gel-like acrylic adhesive material, has a layer thickness of 25 to 100 μm, and the adhesive material has a hardness greater than 0 and 350,000 μN or less. The manufacturing method of the three-dimensional image display apparatus of Claim 7 which uses the thing which is in a range and whose holding power after bonding in 40 degreeC is 8-20N / 20mm. In the second bonding step, the second bonding agent layer is made of a transparent gel-like acrylic adhesive, and the storage rigidity at 30 to 70 ° C. is in the range of greater than 0 to 70000 Pa or less, and the loss rigidity is The manufacturing method of the three-dimensional image display apparatus of Claim 7 which uses what is in the range of more than 0 and 20000 Pa or less. In the second bonding step,
The laminate including the image display panel, the first bonding agent layer, the light shielding layer, the polarizing plate, the second bonding agent layer, and the laminate including the retardation element, from one end side to the other end side. The laminating roller that pressurizes with a force belonging to a predetermined range from above and below in the laminating direction is run at a speed belonging to the predetermined range, and the laminating body is bonded,
At the time of the bonding, the position of the edge on the other end side of the retardation element is set so that the retardation element has a gap with respect to the polarizing plate on the other end side with respect to the bonding roller. The manufacturing method of the three-dimensional image display apparatus of Claim 13 or 14 which moves the position of the said edge in conjunction with the driving | running state of the said roller for bonding while hold | maintaining. Including a positioning step of performing a planar alignment for the retardation element prior to the second bonding step,
In the positioning step, irradiation light from a light source disposed on one side of the retardation element is caused to reach the retardation element via a polarizing plate disposed between the light source and the retardation element. The light transmitted through the phase difference element is imaged by an imaging device disposed on the other side of the phase difference element, so that the right-eye image display unit and the left-eye image display unit in the phase difference element The manufacturing method of the three-dimensional image display apparatus of Claim 7 which recognizes a boundary. While including the positioning process which performs planar alignment about the image display panel prior to the first bonding process or the second bonding process,
In the positioning step, a light source disposed on one side of the image display panel emits irradiation light having a light quantity that transmits the image display panel even when the light transmittance of the image display panel is minimized. The solid position of the image display panel is recognized by imaging the light transmitted through the image display panel with an imaging device disposed on the other side of the image display panel. Manufacturing method of image display apparatus. The manufacturing method of the three-dimensional image display apparatus of Claim 7 including the annealing process of performing the heat processing for a predetermined time at predetermined temperature with respect to the said phase difference element which is a component of the said laminated body prior to a said 2nd bonding process. Prior to transferring the light shielding layer from the base material in the light shielding layer forming step, including a positioning step of aligning the light shielding layer and the retardation element,
In the positioning step, the irradiation light from the light source is sequentially transmitted through the base material and the phase difference element, and then reaches the image pickup apparatus through a polarizing plate disposed on the image pickup apparatus side with respect to the phase difference element. And aligning the light shielding layer and the phase difference element based on an imaging result when the imaging device is focused on the light shielding layer and an imaging result when the focus is set on the phase difference element. Item 9. A method for manufacturing a stereoscopic image display device according to Item 8.

Images