JP4471022B2 - Electro-optical device substrate and electronic apparatus - Google Patents

Description

  The present invention relates to an electro-optical device, a method for manufacturing an electro-optical device, and an electronic apparatus, and more particularly to a structure for positioning an electro-optical panel.

  In general, a liquid crystal display panel, which is a kind of electro-optical panel constituting an electro-optical device, is used by being incorporated in a casing of an electronic device such as a mobile phone. In this case, the electronic device is provided with a display window in order to make the display area of the liquid crystal display panel visible from the outside. At this time, if the opening range of the display window and the display area of the liquid crystal display panel deviate from the normal positional relationship, a mismatch occurs between the display window of the electronic device and the display screen, resulting in a defective product. There is a problem that the quality of the product is impaired by the appearance around the part.

  As a conventional structure of this type of electro-optical device, the electro-optical panel is fixed on the frame after fixing the electro-optical panel on the frame, and then the electro-optical panel is fixed to the upper case with the frame as a reference. A structure housed in a lower case is known (for example, see Patent Document 1 below).

JP 2005-99616 A

  However, Patent Document 1 has a problem that a jig is required for positioning the electro-optical panel with respect to the frame.

  SUMMARY An advantage of some aspects of the invention is to provide a structure and a manufacturing method of an electro-optical device or an electronic apparatus that can position an electro-optical panel with respect to a frame without using a jig. There is.

The present invention can be realized as the following forms or application examples.
The electro-optical device is attached to the electro-optical panel, the panel support that supports the electro-optical panel from either the front or back side of the electro-optical panel, and the panel support from the other side of the front or back side. The electro-optic panel has at least two outer edges facing each other in plan view, and the panel support is a pair of the outer edges corresponding to the two outer edges of the electro-optic panel. A peripheral wall and a pair of engagement structures formed on the pair of peripheral walls, and the mounting body is erected from a top plate portion and a peripheral edge of the top plate portion, Two outer edges, a pair of side walls corresponding to the pair of peripheral walls, a pair of panel positioning guides formed from the inner surface of the top plate to the pair of side walls, and the pair of side walls. Together with the pair A pair of protrusions that are formed toward the outside of the side wall and engage with the pair of engagement structures, and the pair of panel positioning guide portions guide each of the two outer edges. And guiding the electro-optical panel. According to this configuration, the pair of side walls on which the pair of panel positioning guide portions are formed are configured so that the pair of panel positioning guide portions guide each of the two outer edges of the electro-optical panel, thereby Since outward stress is expressed and the outwardly protruding protrusions of the pair of side walls are securely and firmly engaged with the engagement structure formed on the pair of peripheral walls by the stress. Further, it is possible to more reliably align the electro-optical panel and the mounting body, and it is possible to obtain a stronger holding structure between the panel support body and the mounting body.
The electro-optical device includes an electro-optical panel, a panel support that supports the electro-optical panel from either the front or back side of the electro-optical panel, and the panel support that is mounted from the other side of the front or back side. And the electro-optic panel has at least two outer edges facing each other in plan view, and the mounting body stands from a top plate portion and a peripheral edge of the top plate portion. A pair of side walls corresponding to the two outer edges of the electro-optical panel, and projecting from the top plate portion toward the electro-optical panel, and inwardly spaced from the pair of side walls. A pair of formed panel positioning guides, wherein the pair of panel positioning guides guide the electro-optical panel by guiding each of the two outer edges. According to this configuration, the mounting body includes the pair of panel positioning guide portions that are formed so as to protrude from the top plate portion and are spaced apart from the pair of side walls. Stress generated when guiding each of the two outer edges can be released, and excessive stress can be suppressed from being applied to the electro-optical panel from the panel positioning guide.

  Application Example 1 An electro-optical panel, a panel support that supports the electro-optical panel from either the front or back side of the electro-optical panel, and the panel support that is mounted from the other side of the front or back side The electro-optical panel has at least two outer edges facing each other in plan view, and the mounting body guides each of the two outer edges to thereby provide the electro-optical panel. An electro-optical device having a pair of panel positioning guides for guiding the light.

The electro-optical device according to the application example 1 includes an electro-optical panel, a panel support body, and a mounting body. The panel supporter supports the electro-optic panel from either one of the front and back sides of the electro-optic panel. The mounting body is mounted on the panel support from the other side of the front and back of the electro-optical panel. This mounting body has a pair of panel positioning guide portions for guiding the electro-optical panel. The electro-optical panel has at least two outer edges facing each other in plan view. The pair of panel positioning guides guide the electro-optical panel by guiding each of the two outer edges.
According to this configuration, since the two outer edges of the electro-optical panel are guided by the pair of panel positioning guide portions, the position of the electro-optical panel is regulated from both sides of the two outer edges. For this reason, the position of the electro-optical panel with respect to the mounting body can be regulated without using a jig.

  Application Example 2 In the electro-optical device described above, one of the pair of panel positioning guide portions is opposite to the one outer edge of the two outer edges. And the other panel positioning guide portion of the pair of panel positioning guide portions faces the other outer edge of the two outer edges, and the one panel positioning guide portion and The electro-optical device is characterized in that an interval between the other panel positioning guide portion is shorter toward the other side than the electro-optical panel.

  In Application Example 2, one of the pair of panel positioning guides faces one of the two outer edges, and the other of the pair of panel positioning guides faces the other of the two outer edges. ing. Further, the interval between one panel positioning guide and the other panel positioning guide is shorter toward the other side than the electro-optical panel. With this configuration, the two outer edges of the electro-optical panel can be easily guided.

  Application Example 3 In the above electro-optical device, the two outer edges are in contact with the panel positioning guide portions, respectively.

  In Application Example 3, since the two outer edges are in contact with the panel positioning guides, the electro-optical panel can be held by the pair of panel positioning guides.

  Application Example 4 In the above electro-optical device, each of the two outer edges and each of the panel positioning guides are separated from each other.

  In Application Example 4, since each of the two outer edges and each panel positioning guide portion are separated from each other, the external force received by the electro-optical panel from the pair of panel positioning guide portions can be suppressed low.

  Application Example 5 In the above electro-optical device, the side walls corresponding to the pair of panel positioning guide portions of the mounting body are in contact with the inner walls of the panel support body, and are deformed inward. The electro-optical device, wherein the panel positioning guide portion is in contact with the two outer edges of the electro-optical panel by the deformed side wall.

  With this configuration, the pair of panel positioning guides can be brought into contact with the two outer edges of the electro-optical panel.

  Application Example 6 In the above electro-optical device, the pair of side walls corresponding to the pair of panel positioning guide portions of the mounting body have outward projecting portions, and the panel support body Has a pair of side walls opposed to the projecting portions of the mounting body, and the pair of side walls of the panel support has an inner space between the pair of side walls at the end side of the pair of side walls. And a pair of protrusions of the mounting body, the inner wall portion having a first interval narrower than an outer interval between the pair of protrusions and a second interval wider than the first interval. The electro-optical device is characterized in that the shape portion is disposed to face the inner wall portion having the second interval of the panel support.

  Application Example 7 In the electro-optical device described above, a pair of side walls corresponding to the pair of panel positioning guide portions of the mounting body have protrusions facing outward, and the panel support body Has a pair of side walls opposed to the protrusions of the mounting body, and the pair of side walls of the panel support body is an inner space between the pair of side walls from the end side of the pair of side walls. Is set to be narrower than the outer space between the pair of projecting portions, and the pair of side walls of the panel support are respectively opened at positions facing the projecting portions of the mounting body. The electro-optical device is characterized in that a pair of projecting portions of the mounting body is engaged with the openings of the panel support.

  Application Example 8 In the above electro-optical device, the electro-optical device includes a member interposed between each of the pair of panel positioning guide portions and each of the two outer edges. Optical device.

  The electro-optical device according to the application example 8 includes a member interposed between each of the pair of panel positioning guides and each of the two outer edges. With this configuration, the electro-optical panel can be reduced from being damaged by the pair of panel positioning guides.

  Application Example 9 In the electro-optical device described above, the panel support and the electro-optical panel are bonded via an adhesive layer, and the adhesive layer is bonded to the pair of panel positioning guides by the pair of panel positioning guides. An electro-optical device characterized in that the electro-optical device has a movable adhesive force.

  In Application Example 9, since the panel support and the electro-optical panel are bonded via the adhesive layer, the force with which the panel support supports the electro-optical panel can be increased. Here, the adhesive layer has an adhesive force that allows the electro-optical device to move by the pair of panel positioning guides. For this reason, the position of the electro-optical panel relative to the mounting body can be corrected by the pair of panel positioning guides.

  Application Example 10 In the electro-optical device described above, at least two pairs of the panel positioning guide portions facing each other in different directions are provided.

  In Application Example 10, since at least two pairs of panel positioning guides facing each other in different directions are provided, the position of the electro-optical panel can be easily regulated in different directions. it can. Thereby, it is possible to further improve the positioning accuracy of the electro-optical panel.

  Application Example 11 An electro-optical panel, a panel support that supports the electro-optical panel from one of the front and back sides of the electro-optical panel, and the panel support that is mounted from the other side of the front and back sides. A mounting body, wherein the electro-optical panel has at least two outer edges facing each other in a plan view, and the mounting body has each of the two outer edges. A first step of guiding the electro-optic panel by guiding the panel positioning guide portion; and supporting the electro-optic panel on the panel support; and after the first step, the panel A second step of mounting the mounting body on a support, and in the first step, the electro-optical panel is moved in a state where the electro-optical panel is movable with respect to the panel support. An electro-optical device characterized in that the mounting body is mounted on the panel support body while the pair of panel positioning guide portions are in contact with the two outer edges in the second step. Device manufacturing method.

The electro-optical device according to the manufacturing method of Application Example 11 includes an electro-optical panel, a panel support body, and a mounting body. The panel supporter supports the electro-optic panel from either one of the front and back sides of the electro-optic panel. The mounting body is mounted on the panel support from the other side of the front and back of the electro-optical panel. This mounting body has a pair of panel positioning guide portions for guiding the electro-optical panel. The electro-optical panel has at least two outer edges facing each other in plan view. The pair of panel positioning guides guide the electro-optical panel by guiding each of the two outer edges.
The manufacturing method of Application Example 11 includes a first step and a second step. The first step is a step of supporting the electro-optical panel on the panel support. The second step is a step of mounting the mounting body on the panel support. The second step is performed after the first step.
In the first step, the electro-optical panel is supported by the panel support in a state where the electro-optical panel is movable with respect to the support. In the second step, the mounting body is mounted on the panel support while the pair of panel positioning guide portions are brought into contact with the two outer edges.
According to this manufacturing method, since the two outer edges can be guided by the pair of panel positioning guide portions, the position of the electro-optical panel can be regulated from both sides of the two outer edges. For this reason, the position of the electro-optical panel with respect to the mounting body can be regulated without using a jig.

  Application Example 12 An electronic apparatus comprising the electro-optical device described above and a control unit of the electro-optical device.

In the electronic apparatus of Application Example 12, the electro-optical device includes an electro-optical panel, a panel support body, and a mounting body. The panel supporter supports the electro-optic panel from either one of the front and back sides of the electro-optic panel. The mounting body is mounted on the panel support from the other side of the front and back of the electro-optical panel. This mounting body has a pair of panel positioning guide portions for guiding the electro-optical panel. The electro-optical panel has at least two outer edges facing each other in plan view. The pair of panel positioning guides guide the electro-optical panel by guiding each of the two outer edges.
According to this electro-optical device, since the two outer edges of the electro-optical panel are guided by the pair of panel positioning guide portions, the position of the electro-optical panel is regulated from both sides of the two outer edges. For this reason, the position of the electro-optical panel with respect to the mounting body can be regulated without using a jig. Further, even if there is a dimensional error in the electro-optical panel, the shift of the center position of the electro-optical panel can be made smaller than this dimensional error. As a result, it is possible to easily improve the positioning accuracy of the electro-optical panel.
In the electronic apparatus having the electro-optical device, it is possible to easily improve the positioning accuracy of the electro-optical panel.

  Embodiments will be described with reference to the accompanying drawings. In the following embodiments, a liquid crystal display device which is one of electro-optical devices will be described as an example. In a liquid crystal display device, a liquid crystal display panel is used as an electro-optical panel. The electro-optical device is not limited to a liquid crystal display device, and various electro-optical devices such as an organic EL (Electro Luminescence) device and an electrophoretic display device may be employed.

[First Embodiment]
FIG. 1 is a schematic exploded perspective view of an electro-optical device (liquid crystal display device) 100 according to the first embodiment. The electro-optical device 100 includes an illumination unit 110 constituting a backlight, an electro-optical panel (liquid crystal display panel) 120 disposed on the front side (observation side) of the illumination unit 110, a panel support 130, and a mounting body. 140.

  The illumination unit 110 includes a light source 111 composed of an LED (light emitting diode), a cold cathode tube, and the like, and light emitted from the light source 111 from a light incident surface (end surface) 112a and a light emitting surface (front surface) 112b. A light guide plate 112 that exits from the light source. Here, a plurality of light sources 111 are arranged on the wiring board (flexible wiring board) 113 along the width direction of the light incident surface 112a. A reflection sheet 114 is disposed behind the light guide plate 112. Further, as will be described later, it is preferable that an optical sheet (not shown) is disposed on the light emitting surface 112b. Here, the light guide plate 112 is configured in a rectangular shape in plan view.

  The electro-optical panel 120 includes a transparent substrate 121 and a substrate 122 made of glass or the like, and an electro-optical material (liquid crystal) (not shown) disposed therebetween. The electro-optical panel 120 has an outer edge 120K, an outer edge 120L, an outer edge 120M, and an outer edge 120N. The outer edge 120K and the outer edge 120L face each other. The outer edge 120M and the outer edge 120N face each other. The direction in which the outer edges 120K and 120L face each other and the direction in which the outer edges 120M and 120N face each other intersect in plan view.

  The substrate 121 is provided with a substrate protruding portion 121T protruding from the substrate 122. A semiconductor chip 123, a wiring board (flexible wiring board) 124, and the like constituting a driving circuit are mounted on the board extending portion 121T. Note that polarizing plates 125 and 126 (see FIG. 2 for 125) are arranged (attached) on the outer surfaces of the substrates 121 and 122 as necessary. The electro-optical panel 120 is also configured in a rectangular shape in plan view, and its display area 120A is also configured in a rectangular shape.

The panel support 130 includes a lower frame 131 and a support frame 132 accommodated in the lower frame 131. Although not particularly limited, the lower frame 131 is preferably a metal frame made of a metal such as stainless steel or aluminum. The support frame 132 is preferably a resin frame made of synthetic resin.
In the present embodiment, the lower frame 131 is configured in a rectangular shape in plan view, and has a container shape with an edge having an open top. The support frame 132 is configured in a rectangular shape in a plan view, and has a container shape with an edge having an open top.

  In addition, as the support frame 132, the structure of the frame shape (rectangular frame shape) opened up and down can also be employ | adopted. In addition, a configuration in which the lower frame 131 and the support frame 132 are integrally formed of the same material may be employed. Furthermore, a configuration in which the lower frame 131 and the support frame 132 are integrated with different materials by insert molding or the like may be employed. In the present embodiment, the support frame 132 is positioned in at least the plane direction by being inserted into the lower frame 131. However, the support frame 132 may be disposed in the lower frame 131 so as to be movable in the plane direction.

  The lighting unit 110 is accommodated in the support frame 132 and positioned. In addition, the electro-optical panel 120 is disposed on a support surface 132 a provided around the support frame 132. In this embodiment, the electro-optical panel 120 is bonded to the support surface 132a via the double-sided adhesive tape 133. The double-sided adhesive tape 133 has adhesive layers on the front and back, and adheres the electro-optical panel 120 and the support frame 132. That is, the electro-optical panel 120 and the panel support 130 are bonded via the adhesive layer of the double-sided adhesive tape 133. However, the double-sided adhesive tape 133 holds the electro-optical panel 120 so that the electro-optical panel 120 can be moved in the plane direction to the extent necessary for correcting the positional deviation of the electro-optical panel 120 by the mounting body 140 described later. If the support frame 132 is configured to be movable in the plane direction with respect to the lower frame 131 as described above, the electro-optical panel 120 may be in a state of being completely fixed to the support frame 132. .

  The mounting body 140 includes a main body, a guide part 141, a guide part 142, a guide part 143, and a guide part 144. The main body of the mounting body 140 includes a top plate portion 140R, a side wall 140K, a side wall 140L, a side wall 140M, and a side wall 140N. The mounting body 140 corresponds to an upper frame that is mounted on the lower frame 131. The mounting body 140 has an opening at the bottom, and is configured to be mounted on the panel support 130. A display window 140a is provided on the top panel 140R. For this reason, the display region 120A of the electro-optical panel 120 can be viewed from the observation side (upper side in the drawing) through the display window 140a. Although not particularly limited, the body of the mounting body 140 is preferably made of a metal such as stainless steel or aluminum or a synthetic resin such as polyethylene.

In the present embodiment, the mounting body 140 is configured to be mounted on the panel support 130. When the mounting body 140 is mounted on the panel support 130, the side wall 140K, the side wall 140L, the side wall 140M, and the side wall 140N of the mounting body 140 are inserted inside the peripheral wall 131S of the lower frame 131 of the panel support 130. The
Here, each of the side wall 140K and the side wall 140L is provided with an engaging portion 140t. Further, the lower frame 131 is provided with an engagement hole 131t in a peripheral wall 131S forming a side wall. The engaging holes 131t are provided at positions facing the respective engaging portions 140t when the mounting body 140 is mounted on the panel support 130. For this reason, when the side wall 140K, the side wall 140L, the side wall 140M, and the side wall 140N of the mounting body 140 are inserted inside the peripheral wall 131S of the lower frame 131, the engaging portion 140t and the engaging hole 131t are engaged. Match. Thereby, the mounting body 140 is attached to the panel support body 130. A step portion 132 b is provided on the outer peripheral portion of the support frame 132. For this reason, when the support frame 132 is accommodated in the lower frame 131, a space is secured between the peripheral wall 131 </ b> S of the lower frame 131 and the support frame 132. The side wall 140K, the side wall 140L, the side wall 140M, and the side wall 140N of the mounting body 140 are received in this space.

  The guide part 141, the guide part 142, the guide part 143, and the guide part 144 are provided inside the main body of the mounting body 140. In the present embodiment, a plurality (two each) of the guide portions 141 to 144 are provided. Each of the guide portions 141 to 144 is configured by a protrusion protruding from the top plate portion 140R in the mounting direction (downward in the drawing) of the mounting body 140 with respect to the panel support body 130.

Each guide part 141 and each guide part 142 are provided in the position which mutually opposes, and comprise a pair. Each guide part 143 and each guide part 144 are provided at positions facing each other, and constitute a pair. The direction in which each guide part 141 and each guide part 142 face each other and the direction in which each guide part 143 and each guide part 144 face each other are different from each other and intersect in plan view.
In this embodiment, two pairs of guide portions 141 and 142 and a pair of guide portions 143 and 144 are provided, but the number of sets is not limited to this, and at least one set is provided. It only has to be done.

  In the present embodiment, each of the guide portions 141 to 144 has a triangular pyramid shape that gradually decreases in thickness from the top plate portion 140R side (upper side in the drawing) toward the distal end side (lower side in the drawing). Each guide part 141 has two inclined surfaces 141a. Each guide part 142 has two inclined surfaces 142a. Each guide part 143 has two inclined surfaces 143a. Each guide part 144 has two inclined surfaces 144a.

The two inclined surfaces 141a of one guide part 141 share the ridgeline 145 shown in FIG. The same applies to the other guide portions 142 to 144, and each guide portion 142 to 144 has a ridge line 145.
Each inclined surface 141a-144a has faced the mounting direction diagonally inner side. That is, each of the inclined surfaces 141a to 144a is inclined with respect to the mounting direction and is directed toward the electro-optical panel 120 as viewed in FIG.

  A ridge line 145 shared by the two inclined surfaces 141a of each guide portion 141 is inclined with respect to the mounting direction and faces the outer edge 120K of the electro-optical panel 120. Similarly, a ridge line 145 shared by the two inclined surfaces 142a of each guide portion 142 has an inclination with respect to the mounting direction and faces the outer edge 120L of the electro-optical panel 120. A ridge line 145 shared by the two inclined surfaces 143a of each guide portion 143 has an inclination with respect to the mounting direction and faces the outer edge 120M of the electro-optical panel 120. A ridge line 145 shared by the two inclined surfaces 144 a of each guide portion 144 has an inclination with respect to the mounting direction and faces the outer edge 120 </ b> N of the electro-optical panel 120.

  With the above-described configuration, the ridge lines 145 come into contact with the outer edges 120K, 120L, 120M, and 120N of the electro-optical panel 120 in each of the guide portions 141 to 144 as described later. For this reason, almost no restraining force in the width direction is applied, and there is no possibility that unnecessary distortion or the like is applied to the electro-optical panel 120. In addition, each guide part 141-144 is not limited to the structure provided with the two inclined surfaces 141a-144a, respectively, The structure provided with the single inclined surface can also be employ | adopted. For example, it is conceivable to provide a flat inclined surface having a width direction along each outer edge 120K, 120L, 120M, 120N of the corresponding electro-optical panel 120 as a single inclined surface. In addition, a configuration in which the guide portions 141 to 144 have rib shapes extending along the outer edges 120K, 120L, 120M, and 120N of the electro-optical panel 120 may be employed.

  In the present embodiment, the pair of guide portions 141 and 142 are provided at positions sandwiching the arrangement region of the electro-optical panel 120, and the inclined surfaces 141a and 142a directly face the outer edges 120K and 120L of the electro-optical panel 120, respectively. So as to face each other. The other pair of guide portions 143 and 144 are provided at positions sandwiching the arrangement region of the electro-optical panel 120 in a direction different from the guide portions 141 and 142, and the inclined surfaces 143 a and 144 a are provided on the electro-optical panel 120. The outer edges 120M and 120N are arranged so as to face each other directly. As described above, by providing a plurality of sets of guide portions 141 and 142 and guide portions 143 and 144 that sandwich the electro-optical panel 120 from different directions, the positioning accuracy of the electro-optical panel 120 in the planar direction can be further improved. it can.

  Each guide part 141-144 is provided in the position corresponding to each outer edge 120K, 120L, 120M, 120N of the electro-optical panel 120 of the mounting body 140. Further, the guide portions 141 to 144 are made of a material that is more easily elastically deformed than the main body of the mounting body 140. In the present embodiment, the main body of the mounting body 140 is composed of a metal frame. Each guide part 141-144 is comprised by the resin protrusion integrally formed with the main body of the mounting body 140 by resin molding. In addition, the structure of the mounting body 140 is not limited to these structures, The structure by which the main body of the mounting body 140 and each guide part 141-144 were integrally formed with the same raw material (for example, synthetic resin) may be employ | adopted. .

  2 is a cross-sectional view of the present embodiment before the mounting body 140 is mounted, and FIG. 3 is a cross-sectional view after the mounting. The lighting unit 110 is accommodated in the panel support 130. Here, an optical sheet 115 is disposed on the light guide plate 112 as necessary. The electro-optical panel 120 is disposed on the support frame 132 of the panel support 130 that houses the illumination unit 110. Here, the electro-optical panel 120 may be bonded to the support surface 132 a of the support frame 132 via the double-sided adhesive tape 133. However, if the electro-optical panel 120 is strictly fixed, the displacement cannot be corrected. Therefore, the electro-optical panel 120 needs to have an adhesive layer that can move in the plane direction.

Next, the mounting body 140 is mounted on the panel support 130 from above. At this time, the side wall 140K, the side wall 140L, the side wall 140M, and the side wall 140N of the mounting body 140 are inserted between the peripheral wall 131S of the lower frame 131 and the support frame 132, as shown in FIG.
Here, in the electro-optical panel 120, the interval between the outer edge 120K and the outer edge 120L is set to H1. In addition, in the mounting body 140, the inner space between the guide portion 141 and the guide portion 142 on the top plate portion 140R side is set to H2. Further, the inner space between the guide portion 141 and the guide portion 142 on the front end (end portion on the electro-optical panel 120 side) side is set to H3. These intervals H1, H2, and H3 satisfy the relationship of the following formula (1).
H3>H1> H2 (1)
The above relationship is also satisfied between the pair of guide portions 143 and 144 and the outer edges 120M and 120N.

Due to the above relationship, in the process of mounting the mounting body 140 on the panel support 130, the guide portions 141 and 142 abut on the outer edges 120K and 120L, as shown in FIG. Similarly, the guide portions 143 and 144 abut on the outer edges 120M and 120N in the mounting process.
For this reason, the position of the electro-optical panel 120 in the planar direction can be corrected by an external force received from each of the guide portions 141 to 144. Here, each guide part 141-144 has the rigidity which can contact | abut each outer edge 120K, 120L, 120M, 120N of the electro-optical panel 120, and can correct the planar position.

  Depending on the initial planar position of the electro-optical panel 120 and the distance between the pair of guide portions 141 and 142, the planar position may be corrected by contacting only one of the pair of guide portions 141 and 142. obtain. Here, the intervals H2 and H3 and the inclination angles of the inclined surfaces 141a and 142a are determined according to the allowable width of the planar position of the electro-optical panel 120, the size and height variations of both outer edges of the electro-optical panel 120, and the like. Is done.

The engaging portion 140t engages with the engaging hole 131t as shown in FIG. Thereby, mounting | wearing of the mounting body 140 with respect to the panel support body 130 is completed.
Here, as shown in FIG. 2, in the lower frame 131, the inner space between the surrounding walls 131S facing each other with the electro-optical panel 120 interposed therebetween is set to H4. Further, in the mounting body 140, the interval between the engaging portions 140t facing each other is set to H5. These intervals H4 and H5 satisfy the relationship of the following formula (2).
H5> H4 (2)
Due to the above relationship, the engaging portion 140t and the engaging hole 131t can be engaged.

  In the present embodiment, the inner space between the pair of guide portions 141 and 142 is shortened from the tip side toward the top plate portion 140R.

  In the present embodiment, after the mounting body 140 is mounted on the panel support body 130, the guide portions 141 to 144 are in contact with the electro-optical panel 120 as shown in FIG. Here, each guide part 141-144 is comprised with the raw material which is easy to elastically deform. For this reason, even if each guide part 141-144 contact | abuts the electro-optical panel 120 after the mounting body 140 is mounted | worn with the panel support body 130, it is low that an excessive stress and distortion arise in the electro-optical panel 120. Can be suppressed. In FIG. 3, the shape of each guide portion 141 and 142 before elastic deformation is indicated by a two-dot chain line.

  In the present embodiment, when the mounting body 140 is mounted on the panel support body 130, the planar position of the electro-optical panel 120 is corrected from both the outer edge 120 </ b> K side and the outer edge 120 </ b> L side by the pair of guide portions 141 and 142. Similarly, the planar position of the electro-optical panel 120 is corrected from both sides of the outer edge 120M side and the outer edge 120N side by the pair of guide portions 143 and 144. For this reason, even if there is a dimensional error in the electro-optical panel 120, the positional shift of the display area 120A with respect to the display window 140a can be made smaller than this dimensional error. As a result, the positioning accuracy of the electro-optical panel 120 can be easily improved.

  In the present embodiment, a configuration in which the electro-optical panel 120 and the panel support 130 (support frame 132) are bonded via the double-sided adhesive tape 133 is employed. However, the electro-optical panel 120 and the panel support are used. The configuration of 130 is not limited to this. As a configuration of the electro-optical panel 120 and the panel support 130, a configuration in which the double-sided adhesive tape 133 is omitted may be employed. In addition, a configuration in which the support frame 132 is movable in the plane direction with respect to the lower frame 131 may be employed.

  According to these configurations, the position of the electro-optical panel 120 with respect to the lower frame 131 can be changed with a slight external force. For this reason, when the mounting body 140 is mounted on the panel support 130, the external force that the electro-optical panel 120 receives from each of the guide portions 141 to 144 can be suppressed low. Thereby, it is possible to suppress the electro-optical panel 120 from being damaged by the guide portions 141 to 144. Furthermore, the positioning accuracy of the electro-optical panel 120 can be further improved.

  In these configurations as well, the guides 141 to 144 and the electro-optical panel 120 are kept in contact after the mounting body 140 is mounted on the panel support 130. For this reason, the holding force of the electro-optical panel 120 in the electro-optical device 100 is ensured. However, the configuration in which the electro-optical panel 120 and the panel support 130 are bonded via the double-sided adhesive tape 133 is preferable in that the holding power of the electro-optical panel 120 in the electro-optical device 100 can be increased.

  Further, in the present embodiment, a configuration is adopted in which each guide portion 141 to 144 abuts each outer edge 120K, 120L, 120M, 120N of the electro-optical panel 120. However, the present invention is not limited to this configuration, and a configuration in which another member is interposed between each guide portion 141 to 144 and each outer edge 120K, 120L, 120M, 120N may be employed. In this case, when the mounting body 140 is mounted on the panel support 130, the guide portions 141 to 144 are configured to guide the outer edges 120K, 120L, 120M, and 120N of the electro-optical panel 120 as a result. That's fine. As another member, for example, a frame material that covers the outer peripheral portion of the electro-optical panel 120, a buffer material provided between the electro-optical panel 120 and each of the guide portions 141 to 144, or a display area 120A of the electro-optical panel 120 For example, a cover glass that protects the screen can be considered. This also applies to other embodiments described later.

For example, when another member is a cover glass, each guide part 141-144 is the outer edge of the cover glass 301, as shown to FIG. 4A which is an enlarged view of the site | part corresponded to the A section in FIG. It abuts on 301K.
For example, when another member is a buffer material, each guide part 141-144 is the buffer material 303 as shown in FIG.4 (b) which is an enlarged view of the site | part corresponded to the A section in FIG. Abut. The contact portion 303T of the cushioning material 303 is deformed by an external force received from each of the guide portions 141 to 144. The buffer material 303 is provided outside the display area 120 </ b> A of the electro-optical panel 120. For this reason, the image displayed on the display area 120 </ b> A can be visually recognized without being obstructed by the buffer material 303.
In the present embodiment, the buffer material 303 is provided outside the polarizing plate 126. For this reason, it can avoid that the buffer material 303 and the polarizing plate 126 overlap. Thereby, the thickness of the electro-optical device 100 can be easily reduced.

  Further, in the present embodiment, at least in the process in which the mounting body 140 is mounted on the panel support body 130, each of the guide portions 141 to 144 may abut on the electro-optical panel 120 or the above member. Accordingly, the planar position of the electro-optical panel 120 can be regulated in the process in which the mounting body 140 is mounted on the panel support 130. Accordingly, after the mounting body 140 is mounted on the panel support 130 as in other embodiments described later, the guide portions 141 to 144 and the electro-optical panel 120 (or the above-described members, the same applies hereinafter) are brought into contact with each other. Instead, a spaced configuration may be employed.

[Second Embodiment]
A second embodiment will be described. In the second embodiment, as shown in FIG. 5, a guide part 241 is adopted instead of the guide part 141 in the first embodiment, and a guide part 242 is adopted instead of the guide part 142. Further, although not shown, a guide unit 243 is employed instead of the guide unit 143 in the first embodiment, and a guide unit 244 is employed instead of the guide unit 144.
Except for these points, the electro-optical device 100 of the second embodiment has the same configuration as the electro-optical device 100 of the first embodiment. Therefore, in the following, the same parts as those in the first embodiment are denoted by the same reference numerals, and the description thereof is omitted.

  As shown in FIG. 6, each guide portion 241 to 244 is formed inside the side wall 140K, the side wall 140L, the side wall 140M, and the side wall 140N of the mounting body 140. Each guide portion 241 to 244 is fixed from the inner surface of the top plate portion 140R of the mounting body 140 to the inner surfaces of the side wall 140K, the side wall 140L, the side wall 140M, and the side wall 140N. For this reason, each guide part 241 to 244 has increased rigidity compared to each guide part 141 to 144 in the first embodiment. In addition, inclined surfaces 241a, 242a, 243a, and 244a similar to those in the first embodiment are formed in the respective guide portions 241 to 244. Moreover, each guide part 241-244 has a ridgeline 245. Further, each guide portion 241 to 244 is similar to the first embodiment in that the thickness is gradually reduced from the top plate portion 140R side (upper side in the drawing) toward the front end side (lower side in the drawing). is there.

  In the second embodiment, as shown in FIG. 7, when the mounting body 140 is mounted on the panel support body 130, the guide portions 241 and 242 come into contact with the outer edges 120 </ b> K and 120 </ b> L of the electro-optical panel 120, The planar position of the electro-optical panel 120 is restricted. At this time, the engaging portions 140t of the side wall 140K and the side wall 140L of the mounting body 140 are pressed inward by the peripheral wall 131S of the lower frame 131, and the side wall 140K and the side wall 140L are elastically deformed inward. For this reason, each guide part 241,242 formed in the inner surface of the side wall 140K and the side wall 140L is displaced inward with elastic deformation of the side wall 140K and the side wall 140L. At this time, the outer edges 120 </ b> K and 120 </ b> L of the electro-optical panel 120 are pressed inward by the pair of guide portions 241 and 242. At this time, the lower end portions of the side wall 140K and the side wall 140L may be guided by the outer peripheral surface of the support frame 132 as illustrated.

  After that, as shown in FIG. 5, when the engaging portion 140t is engaged with the engaging hole 131t, at least a part of the elastic deformation of the side wall 140K and the side wall 140L is restored, and the guide portions 241 and 242 are not so small. There is a displacement to the outside.

  In the second embodiment, the guide portions 241 and 242 are temporarily displaced inward when the mounting body 140 is mounted on the panel support 130. For this reason, the outer edges 120 </ b> K and 120 </ b> L of the electro-optical panel 120 are guided by the pair of guide portions 241 and 242. Thereby, the planar position of the electro-optical panel 120 can be regulated. Then, since the positions of the guide portions 241 and 242 return to the outside after the mounting is completed, the possibility that the guide portions 241 and 242 give excessive stress or distortion to the electro-optical panel 120 can be reduced.

  In the second embodiment, in a state where the mounting body 140 is mounted on the panel support body 130, the guide portions 241 and 242 contact the outer edges 120K and 120L of the electro-optical panel 120 as shown in FIG. It touches. However, even if the guide portions 241 and 242 are in contact with the outer edges 120K and 120L, the guide portions 241 and 242 that are displaced inward during the mounting process return to the outside after the mounting is completed, so that the stress and strain can be reduced. There is no change.

  In addition, as the support frame 132, the structure of the frame shape (rectangular frame shape) opened up and down can also be employ | adopted. In addition, a configuration in which the lower frame 131 and the support frame 132 are integrally formed of the same material may be employed. Furthermore, a configuration in which the lower frame 131 and the support frame 132 are integrated with different materials by insert molding or the like may be employed. In the present embodiment, the support frame 132 is positioned in at least the plane direction by being inserted into the lower frame 131. However, the support frame 132 may be disposed in the lower frame 131 so as to be movable in the plane direction.

[Third Embodiment]
A third embodiment will be described. In the third embodiment, as shown in FIG. 8, a mounting body 240 is employed instead of the mounting body 140 in the second embodiment, and a panel support body 230 is employed instead of the panel support body 130.
Except for these points, the electro-optical device 100 of the third embodiment has the same configuration as the electro-optical device 100 of the second embodiment. Therefore, in the following, the same parts as those in the second embodiment are denoted by the same reference numerals, and the description thereof is omitted.

In the third embodiment, as shown in FIG. 9, the lower frame 231 and the main body of the mounting body 240 are each composed of a thin metal frame.
The peripheral wall 231S of the lower frame 231 has a thick portion 231T on the upper end side. The thick part 231T has a configuration in which the upper end of the peripheral wall 231S is bent inward. With this bent configuration, an engagement step 231t is formed at the lower end of the thick portion 231T. This folded structure is sometimes called hemming bending.

  The side wall 240K and the side wall 240L of the mounting body 240 have engagement pieces 240t. The engaging piece 240t has a configuration in which the lower ends of the side wall 240K and the side wall 240L are folded outward and extends obliquely upward. In addition, each guide part 241-244 is being fixed over each inner surface of the side wall 240K, the side wall 240L, the side wall 240M, and the side wall 240N from the inner surface of the top plate part 240R of the mounting body 240 as in the second embodiment. Yes. Moreover, it is the same as that of 1st and 2nd embodiment also in the point comprised so that thickness may become small gradually toward the front end side (illustration lower direction) from the top-plate part 240R side (illustration upper direction).

Here, in the lower frame 231, the inner space between the thick portions 231T facing each other with the electro-optical panel 120 interposed therebetween is set to H6. Further, the inner space between the surrounding walls 231S facing each other with the electro-optical panel 120 interposed therebetween is set to H7. These intervals H6 and H7 satisfy the relationship of the following formula (3).
H7> H6 (3)

On the other hand, in the mounting body 240, the outer space between the engaging pieces 240t facing each other is set to H8. The intervals H6 and H8 satisfy the relationship of the following formula (4).
H8> H6 (4)
Due to the above relationship, the engagement piece 240t and the engagement step 231t can be engaged.

  In the third embodiment, by inserting the side wall 240K and the side wall 240L of the mounting body 240 inside the peripheral wall 231S of the lower frame 231, the engagement piece 240t, the side wall 240K, and the side wall 240L are lowered as shown in FIG. The thick portion 231T of the frame 231 is elastically deformed inward. The guide portions 241 and 242 formed on the inner surfaces of the side wall 240K and the side wall 240L are displaced inward as the side walls 240K and 240L are elastically deformed. At this time, the guide portions 241 and 242 are in contact with the outer edges 120K and 120L of the electro-optical panel 120. As a result, the outer edges 120K and 120L of the electro-optical panel 120 are pressed inward by the pair of guide portions 241 and 242, and the planar position of the electro-optical panel 120 is restricted. At this time, the lower end portions of the side wall 240K and the side wall 240L may be guided by the outer peripheral surface of the support frame 132 as illustrated.

  Thereafter, the tip of the engagement piece 240t is engaged with the engagement step 231t as shown in FIG. Thereby, the mounting body 240 is mounted on the panel support 230. At this time, at least a part of the elastic deformation (FIG. 10) of the engagement piece 240t, the side wall 240K, and the side wall 240L is restored as shown in FIG. When at least a part of the elastic deformation of the side wall 240K and the side wall 240L is restored, the guide portions 241 and 242 are displaced outward. Therefore, the guide portions 241 and 242 are separated from the outer edges 120K and 120L of the electro-optical panel 120.

  In the third embodiment, after the mounting body 240 is mounted on the panel support body 230, the external force that the electro-optical panel 120 receives from the guide portions 241 and 242 is released. For this reason, there is no possibility of applying unnecessary stress or distortion to the electro-optical panel 120. However, even in this case, the ridge line 245 faces each of the outer edges 120K, 120L, 120M, and 120N of the electro-optical panel 120 via a slight gap. For this reason, the function of substantially holding the electro-optical panel 120 in the planar direction and the vertical direction is ensured.

In addition, as the support frame 132, the structure of the frame shape (rectangular frame shape) opened up and down can also be employ | adopted. Further, a configuration in which the lower frame 231 and the support frame 132 are integrally formed of the same material may be employed. Furthermore, a configuration in which the lower frame 231 and the support frame 132 are integrated with different materials by insert molding or the like may be employed.
In the present embodiment, the support frame 132 is positioned in at least the plane direction by being inserted into the lower frame 231. However, the support frame 132 and the lower frame 231 are not limited to this configuration, and a configuration in which the support frame 132 is arranged so as to be movable in the plane direction within the lower frame 231 may be employed.

As a configuration in which the lower frame 231 and the support frame 132 are integrated by insert molding, for example, the configuration shown in FIG. 11 is conceivable. In this configuration, the lower frame 231 has a peripheral wall 231 </ b> S sandwiched between the support frame 132 and the side wall portion 132 c. The support frame 132 and the side wall part 132c are integrally formed by insert molding.
With this configuration, the trouble of inserting the support frame 132 into the lower frame 231 can be omitted. Further, the trouble of positioning the support frame 132 with respect to the lower frame 231 can be omitted. For this reason, the manufacturing efficiency of the electro-optical device 100 can be easily improved.

In the first embodiment, one guide portion 141 has two inclined surfaces 141a. A ridge line 145 shared by these two inclined surfaces 141a contacts the electro-optical panel 120, the cover glass 301, the buffer material 303, and the like. The other guide parts 142-144 are the same.
In the second embodiment and the third embodiment, each guide 241 has two inclined surfaces 241a. A ridge line 245 shared by these two inclined surfaces 241a contacts the electro-optical panel 120, the cover glass 301, the buffer material 303, and the like. The other guide parts 242 to 244 are the same.

And in 1st Embodiment, 2nd Embodiment, and 3rd Embodiment, the case where the ridgeline 145 and the ridgeline 245 are a straight line, respectively is illustrated. However, the ridge line 145 and the ridge line 245 are not limited to straight lines, and for example, as shown in FIG. The same applies to a configuration in which one guide portion 141 (241) has a single inclined surface 141a (241a). That is, in the configuration in which one guide portion 141 (241) has a single inclined surface 141a (241a), a curved surface can be applied as the single inclined surface 141a (241a).
That is, the shape of the ridge line 145 and the number of the inclined surfaces 141a and 142a are arbitrary as long as the inner distance between the pair of guide portions 141 and 142 is shortened from the tip side toward the top plate portion 140R. Can be set to The same applies to the other guide parts 143 and 144 and the guide parts 241 to 244.

  In the first embodiment, the second embodiment, and the third embodiment, the ridge line 145 and the ridge line 245 are inclined with respect to the mounting direction in each of the pair of guide portions 141 and 142 (241 and 242). The case where it is doing is illustrated. However, the ridgeline 145 and the ridgeline 245 are not limited to this, and as shown in FIG. 13, only at least one of the pair of guide portions 141 and 142 (241 and 242) is inclined with respect to the mounting direction. Configurations can also be employed. The pair of guide portions 141 and 142 (241 and 242) is configured such that the inner space between the guide portions 141 and 142 (241 and 242) is shortened from the tip side toward the top plate portion 140R (240R) side. Just do it. The same applies to the pair of guide portions 143 and 144 (243 and 244).

  In the first embodiment, the second embodiment, and the third embodiment, each of the guide portions 141 to 144 and the guide portions 241 to 244 corresponds to a panel positioning guide portion. Further, the side walls 140K and 140L and the side walls 240K and 240L correspond to the side walls corresponding to the pair of panel positioning guides. Further, the inner surface of the peripheral wall 131S and the inner surface of the thick portion 231T correspond to the inner wall of the panel support. Further, the engaging portion 140t and the engaging piece 240t correspond to the protruding portion. The interval H6 corresponds to the first interval, and the interval H7 corresponds to the second interval. Further, the peripheral wall 131S corresponds to a pair of side walls opposed to the protrusions of the mounting body. Further, the engagement hole 131t corresponds to the opening.

[Electronics]
An embodiment in which the electro-optical device according to each embodiment described above is mounted on an electronic apparatus will be described. The electronic apparatus 200 is an electronic apparatus in which the electro-optical device 100 is mounted on a display unit, and FIG. 14 shows a mobile phone that is an embodiment of the electronic apparatus according to the present invention. An electronic apparatus 200 shown here includes an operation unit 201 having a plurality of operation buttons, a mouthpiece, and the like, and a display unit 202 having a mouthpiece, and the above-described electro-optical device is provided inside the display unit 202. 100 is incorporated. The display area 120A (see FIG. 1) of the electro-optical device 100 can be visually recognized on the surface (inner surface) of the display unit 202. In this case, a display control circuit (to be described later) that controls the electro-optical device 100 is provided inside the electronic apparatus 200, and this display control circuit determines the display mode of the electro-optical device 100.

  In addition, in the electronic device 200, the mounting bodies 140 and 240 can be configured by a frame fixed to the electronic device 200 side and the casing of the electronic device 200 itself. In this way, the display screen can be set at a position that is highly accurately aligned with the opening shape of the display unit 202.

  FIG. 15 is a schematic configuration diagram illustrating an overall configuration of a control system (display control system) for the electro-optical device 100 in the electronic apparatus. The electronic apparatus shown here includes a display information output source 291, a display information processing circuit 292, a power supply circuit 293, a timing generator 294, and a light source control circuit 295 that supplies power to the illumination unit 110. 290. The electro-optical device (liquid crystal display device) 100 includes an electro-optical panel 120 having the above-described configuration, a drive circuit 127 that drives the electro-optical panel 120, and a backlight for illuminating the electro-optical panel 120. A certain lighting unit (lighting device) 110 is provided. The drive circuit 127 is not limited to an aspect configured with electronic components directly mounted on the electro-optical panel 120 as described above. The drive circuit 127 is mounted on a circuit pattern formed on the substrate surface of the electro-optical panel 120, a circuit board conductively connected to the electro-optical panel 120, or other electronic components such as the wiring board 128 described above. A semiconductor IC chip or a circuit pattern can also be used.

  The display information output source 291 includes a memory such as a ROM (Read Only Memory) or a RAM (Random Access Memory), a storage unit such as a magnetic recording disk or an optical recording disk, and a tuning circuit that tunes and outputs a digital image signal. Is included. The display information output source 291 is configured to supply display information to the display information processing circuit 292 based on various clock signals generated by the timing generator 294 in the form of an image signal having a predetermined format.

  The display information processing circuit 292 includes various known circuits such as a serial-parallel conversion circuit, an amplification / inversion circuit, a rotation circuit, a gamma correction circuit, and a clamp circuit, and executes processing of input display information to obtain image information. Are supplied to the drive circuit 127 together with the clock signal CLK. The drive circuit 127 includes a scanning line drive circuit, a signal line drive circuit, and an inspection circuit. The power supply circuit 293 supplies a predetermined voltage to each of the above-described components.

  The light source control circuit 295 supplies power to the light source of the illumination unit 110 based on the voltage supplied from the power supply circuit 293, and controls whether or not the light source is turned on and its brightness based on a predetermined control signal. ing.

  In addition to the mobile phone shown in FIG. 14, examples of the electronic apparatus according to the present invention include a liquid crystal television, a car navigation device, a pager, an electronic notebook, a calculator, a workstation, a videophone, and a POS terminal. The electro-optical device (liquid crystal display device) according to the present invention can be used as a display unit of these various electronic devices.

1 is a schematic exploded perspective view showing an overall configuration of an electro-optical device according to a first embodiment. FIG. 3 is a schematic cross-sectional view illustrating a state before the mounting body of the electro-optical device according to the first embodiment is mounted. FIG. 3 is a schematic cross-sectional view illustrating a state after the mounting body of the electro-optical device according to the first embodiment is mounted. The enlarged view of the site | part corresponded to the A section in FIG. FIG. 5 is a schematic cross-sectional view illustrating an overall configuration of an electro-optical device according to a second embodiment. FIG. 10 is a schematic cross-sectional view illustrating a state before the mounting body of the electro-optical device according to the second embodiment is mounted. FIG. 6 is a schematic cross-sectional view showing a state in which the electro-optical device according to the second embodiment is being mounted. FIG. 10 is a schematic cross-sectional view illustrating an overall configuration of an electro-optical device according to a third embodiment. FIG. 10 is a schematic cross-sectional view illustrating a state before the mounting body of the electro-optical device according to the third embodiment is mounted. FIG. 10 is a schematic cross-sectional view illustrating a state in which the electro-optical device according to the third embodiment is being mounted. The schematic sectional drawing which shows the structural example which integrated the lower frame and support frame of this embodiment. The schematic sectional drawing which shows the other example of the guide part of this embodiment. The schematic sectional drawing which shows another example of the guide part of this embodiment. The schematic perspective view of an electronic device. The schematic block diagram of the display control system of an electronic device.

Explanation of symbols

  DESCRIPTION OF SYMBOLS 100 ... Electro-optical apparatus, 110 ... Illumination unit, 120 ... Electro-optical panel, 130 ... Panel support body, 131 ... Lower frame, 132 ... Support frame, 140 ... Mounting body (upper frame), 140a ... Display window, 141-144 ... guide part, 141a-144a ... inclined surface.

Claims (6)

An electro-optic panel;
A panel support that supports the electro-optic panel from either one of the front and back sides of the electro-optic panel;
A mounting body mounted on the panel support body from the other side of the front and back sides,
The electro-optic panel has at least two outer edges facing each other in plan view,
The panel support includes a pair of peripheral walls corresponding to the two outer edges of the electro-optical panel, and a pair of engagement structures formed on the pair of peripheral walls,
The wearing body is
The top plate,
A pair of side walls that are erected from the periphery of the top plate portion, and that correspond to the two outer edges of the electro-optic panel and the pair of peripheral walls;
A pair of panel positioning guides for guiding the electro-optic panel formed from the inner surface of the top plate part to the pair of side walls, and formed on the pair of side walls and outward of the pair of side walls. A pair of protrusions that are formed toward and engage with the pair of engagement structures,
The pair of panel positioning guide portions are in contact with the two outer edges of the electro-optical panel via a cushioning material interposed between the two outer edges, and one of the panel positioning guide portions The electro-optical device is characterized in that an interval between the other panel positioning guide portion is shorter toward the other side than the electro-optical panel . In the pair of peripheral walls of the panel support, the inner space between the pair of side walls is narrower than the outer space between the pair of protrusions from the end side of the pair of side walls. An inner wall portion having an interval of 1 and a second interval wider than the first interval,
2. The electro-optical device according to claim 1 , wherein the pair of protrusions of the mounting body are disposed to face an inner wall portion having the second interval of the panel support. The pair of peripheral walls of the panel support body are set such that an inner space between the pair of side walls is narrower than an outer space between the pair of projecting portions from the end side of the pair of side walls. And
Each of the pair of peripheral walls of the panel support is provided with an opening at a position facing each of the protrusions of the mounting body,
The electro-optical device according to claim 1 , wherein each of the pair of protrusions of the mounting body is engaged with each of the openings of the panel support. The panel support and the electro-optical panel are bonded via an adhesive layer,
The adhesive layer is electrically according to any one of claims 1 to 3, wherein the pair of panels the electro-optical device by positioning the guide portion has an adhesive force capable of moving Optical device. The electro-optical device according to any one of claims 1 to 4, wherein at least two sets of said pair of panel positioning guide portion facing along mutually different directions is provided. An electronic apparatus comprising: the electro-optical device according to claim 1; and a control unit of the electro-optical device.

Images