WO2011102021A1

WO2011102021A1 - Switch module

Info

Publication number: WO2011102021A1
Application number: PCT/JP2010/069150
Authority: WO
Inventors: 赤間史朗; 大類学; 内田仁; 赤塚孝寿
Original assignee: 日本メクトロン株式会社
Priority date: 2010-02-17
Filing date: 2010-10-28
Publication date: 2011-08-25
Also published as: JP5486952B2; JP2011171067A; TW201205629A

Abstract

Disclosed is a switch module provided opposite a key substrate. Said switch module decreases the amount of light leaking from the edge area of a reflector towards a key, making it possible to uniformly illuminate the key with light that travels through a light-guide member. The switch module (1) capable of illuminating a key (7) is provided with: a circuit substrate (6) with a metal dome sheet (4) attached to the surface thereof that faces the key substrate (8); a light-guide sheet (3) provided between the key substrate (8) and the circuit substrate (6); an LED (2); and a reflector (9) that causes light emitted from the LED (2) to enter the light-guide sheet (3) via an end thereof. The light-guide sheet (3) has a first surface (3b), facing the key substrate (8), and a second surface (3c) on the other side, facing the circuit substrate (6). A light-absorbing black sheet (12) is provided on the reflector (9) so as to block the path of light that enters the light-guide sheet (3) from the edge area of the reflector (9) and would penetrate the first surface (3b).

Description

Switch module

The present invention relates to a switch module provided to face a key substrate of an electronic device such as a mobile phone or a notebook PC.

2. Description of the Related Art Conventionally, electronic devices such as mobile phones and notebook PCs are provided with a key board having a key portion, and a switch module that switches ON / OFF of the electrical connection by contact or non-contact of the key top is provided on the key board. Opposed. FIG. 5 shows a schematic perspective view of a conventional switch module 100 arranged to face a key substrate 80 having a plurality of key portions 70. FIG. 6 is a schematic sectional view of the switch module 100 shown in FIG.

As shown in FIG. 6A, the switch module 100 is provided with a metal dome 50 including an electrode 55, a circuit board 60, a light guide member 30, and an LED (LightＬＥＤEmitting Diode) 20 as a light emitting element. Yes. The metal dome 50 is integrally held on the circuit board 60 by the metal dome sheet 40, and the light guide member 30 is attached to the metal dome sheet 40 at a predetermined interval by the adhesive layer 35. The light guide member 30 is provided with a light scattering processing portion 30a such as a printing process in which white ink is printed in the form of dots or a prism process on the lower surface of the light guide member 30, and between the light guide member 30 and the LED 20. A reflector (reflective member) 25 for efficiently guiding light emitted from the LED 20 from the end of the light guide member 30 into the light guide member 30 is provided. The end portion of the reflector 25 extends to a position that covers the upper surface of the light guide member 30.

According to such a configuration, the switch can be turned on and off by electrical contact or non-contact between the metal dome 50 and the electrode 55 due to the key portion 70 being pressed downward and the metal dome 50 being deformed. Since the light guide member 30 is provided on the back surface of the key substrate 80, that is, between the key substrate 80 and the metal dome sheet 40, the light emitted from the LED 20 and entering the light guide member 30 is reduced. Each key portion 70 can be illuminated from within the light guide member 30 by being scattered by the light scattering processing portion 30a. Related techniques are disclosed in Patent Documents 1 to 6.

Patent Document 1: Japanese Patent Application Laid-Open No. 2009-246821 Patent Document 2: Japanese Patent Application Laid-Open No. 2008-152951 Patent Document 3: Japanese Patent Application Laid-Open No. 2009-140871 Patent Document 4: Japanese Patent Application Laid-Open No. 2009-187855 Patent Document 5: Japanese Patent Application Laid-Open No. 2009-187855 Japanese Patent Laid-Open No. 2004-139983 Patent Document 6: Japanese Patent Laid-Open No. 2008-226844

However, the conventional configuration has the following problems.

FIG. 6B schematically shows the traveling direction of light in the light guide member 30. Light emitted from the LED 20 and incident into the light guide member 30 from the end of the light guide member 30 by the reflector 25 is repeatedly reflected on the upper and lower surfaces of the light guide member 30, for example, as indicated by L <b> 1 in the drawing. However, the light guide member 30 is advanced. Further, like the light indicated by L2 in the drawing, there is also light scattered by the light scattering processing portion 30a so as to escape from the upper surface of the light guide member 30 in the direction of the key portion 70 (by the light thus scattered. The key unit 70 is illuminated).

However, the light incident on the light guide member 30 is guided in the vicinity of the edge portion of the reflector 25 even though the light scattering processed portion 30a is not formed like the light indicated by L3 and L4 in the drawing. There is light leaking from the upper surface of the optical member 30 toward the key substrate 80. As a result, on the surface of the key substrate 80, there is a problem that the area where the light of L3 and L4 leaks out, that is, the area near the LED 20 is excessively light as compared with other areas.

On the other hand, in general, a switch module that can illuminate a key part has a requirement of “luminance uniformity” that illuminates a plurality of key parts with as uniform luminance as possible. However, in order to satisfy the requirement of “brightness uniformity” in the above-described configuration, it is necessary to avoid placing the key portion 70 in a region where the light is excessively illuminated in the vicinity of the LED 20, and the LED 20 and the key portion 70 (closest to the LED 20) It is necessary to increase the distance. That is, the “distance a” shown in FIG. 6B needs to be set large, and the key portion 7 cannot be arranged in the vicinity of the LED 20. Therefore, this leads to design restrictions in designing the arrangement of the key unit 70. In other words, with the conventional configuration, it is impossible to satisfy the requirement of relaxing the design restrictions in designing the arrangement of the key unit 70 while satisfying the requirement of luminance uniformity.

Therefore, the present invention reduces the amount of light leaking from the vicinity of the edge portion of the reflector toward the key portion in the switch module provided facing the key substrate, and makes the key portion uniform by the light traveling in the light guide member. An object is to provide a switch module that can be illuminated.

In order to achieve the above object, the present invention provides:
A switch module provided opposite to a key board having a key part,
A circuit board having an electrode layer formed on a surface facing the key board;
A light guide member provided between the key board and the circuit board;
A light source element that emits light;
A reflection member that causes light emitted from the light source element to enter the light guide member from an end of the light guide member;
With
A switch that can be turned on and off by moving the key portion with respect to the electrode layer, and that can illuminate the key portion from within the light guide member by light incident on the light guide member. In the module
The light guide member has a first surface facing the key substrate and a second surface on the opposite side and facing the circuit substrate, and the reflection member is a first surface at the end portion. It is provided so as to cover the surface,
In the reflection member,
A light absorptive member is provided that blocks an optical path of light that enters the light guide member and passes through the first surface from the vicinity of the edge portion of the reflecting member.

According to such a configuration, the reflecting member is provided with the light absorbing member that blocks the optical path of the light that enters the light guide member and passes through the first surface from the vicinity of the edge of the reflecting member. By absorbing light by the member, the amount of light leaking from the vicinity of the edge portion of the reflecting member can be reduced. As a result, even if the key part is arranged close to the light source element, it is possible to avoid the problem that the key part is too bright compared to other key parts. Can be alleviated and the requirement for luminance uniformity can be satisfied. In addition, since the light absorbed by the light absorbing member is limited to light that leaks from the vicinity of the edge portion of the reflecting member, the light amount for illuminating the key portion is reduced by providing the light absorbing member. There is almost no risk of this, and the key portion can be illuminated with a sufficient amount of light.

Also,
The light absorbing member is a sheet material having light absorption,
A light absorbing surface that blocks an optical path of light transmitted through the first surface from the vicinity of the edge portion of the reflecting member;
An attachment surface attached to the reflective member;
Have
It is preferable that the mounting surface has an area larger than that of the light absorption surface.

According to such a configuration, since the area of the attachment surface is larger than the area of the light absorption surface, it becomes easy to attach the light absorbing sheet material to the reflecting member, and the attached sheet material is difficult to come off. Therefore, it becomes possible to improve the productivity and durability of the switch module.

Also,
The sheet material is
It is preferable that the reflection member is attached to a surface opposite to the surface facing the light guide member.

According to such a configuration, since the sheet material is attached to the surface of the reflecting member opposite to the surface facing the light guide member, the sheet material can be easily attached to the reflecting member, that is, the productivity is improved and the manufacturing cost is reduced. Reduction can be achieved. For example, when a sheet material is attached to the surface of the reflecting member that faces the light guide member, the sheet material is attached between the reflecting member and the light guide member. There is a possibility that productivity may be reduced and manufacturing costs may be increased. However, with the configuration of the present invention, it is easy to secure a work space, and the sheet material can be easily attached.

In order to achieve the above object, in the present invention,
A switch module provided opposite to a key board having a key part,
A circuit board having an electrode layer formed on a surface facing the key board;
A light guide member provided between the key board and the circuit board;
A light source element that emits light;
A reflection member that causes light emitted from the light source element to enter the light guide member from an end of the light guide member;
With
A switch that can be turned on and off by moving the key portion with respect to the electrode layer, and that can illuminate the key portion from within the light guide member by light incident on the light guide member. In the module
The light guide member has a first surface facing the key substrate and a second surface on the opposite side and facing the circuit substrate, and the reflection member is a first surface at the end portion. It is provided so as to cover the surface,
In the surface facing the first surface in the reflecting member,
A print pattern of light-absorbing ink is formed on an optical path of light that enters the light guide member and passes through the first surface from the vicinity of the edge of the reflective member.

According to this configuration, the light-absorbing property on the light path of the light that enters the light guide member and passes through the first surface from the vicinity of the edge of the reflective member is formed on the surface of the reflective member that faces the first surface. Since the print pattern is formed with the ink, the amount of light leaking from the vicinity of the edge portion of the reflecting member can be reduced by absorbing light in the print pattern. As a result, even if the key part is arranged close to the light source element, it is possible to avoid the problem that the key part is too bright compared to other key parts. Can be alleviated and the requirement for luminance uniformity can be satisfied. Note that the light absorbed by the print pattern with the light-absorbing ink is limited to the light that leaks from the vicinity of the edge portion of the reflecting member, so by forming the print pattern with the light-absorbing ink, the key portion There is almost no fear that the light quantity for illuminating the key will decrease, and the key part can be illuminated with a sufficient quantity of light.

Also,
In the light guide member,
Light scattering processing capable of scattering light incident on the light guide member has been performed, and the key portion from within the light guide member by light scattered in the portion subjected to the light scattering processing Is preferably illuminable.

According to such a configuration, by scattering the light incident on the light guide member, the key portion can be suitably illuminated from the light guide member by the scattered light.

Also,
The light scattering processing is
Print processing for printing light-scattering ink on the light guide member, or
Three-dimensional shape processing for forming a three-dimensional shape having light scattering properties on the light guide member;
Is preferable.

According to such a configuration, the light guide member can be subjected to light scattering processing by a simple processing method. In addition, the printing process referred to here includes, for example, a process of printing white ink in a dot shape, and further, the three-dimensional shape process is applied to the light guide member by a processing method such as mold processing or laser processing. The process which forms an unevenness | corrugation, a prism, etc. is mentioned.

Also,
In the light guide member,
It is preferable that a sheet member having a light transmittance of 100 μm or more and 300 μm or less is used.

According to this configuration, by using a thin light-transmitting sheet member, the entire switch module can be reduced in size, and the light guide member interposed between the key portion and the electrode layer is thin. Therefore, the click feeling transmitted to the user when the user operates the key part can be improved.

As described above, according to the present invention, in the switch module provided to face the key substrate, the amount of light leaking from the vicinity of the edge portion of the reflector toward the key portion is reduced, and the light advances through the light guide member. It is possible to provide a switch module that can uniformly illuminate the key portion with light.

1 is a schematic cross-sectional view of a switch module according to an embodiment of the present invention. 1 is a schematic cross-sectional view of a switch module according to an embodiment of the present invention. The top view of the switch module concerning the embodiment of the present invention. The figure explaining the effect of the switch module concerning the embodiment of the present invention. The schematic perspective view of the conventional switch module. The schematic sectional drawing of the conventional switch module.

DETAILED DESCRIPTION Exemplary embodiments for carrying out the present invention will be described in detail below with reference to the drawings. However, the dimensions, materials, shapes, relative arrangements, and the like of the components described in the following embodiments are not intended to limit the scope of the present invention only to those unless otherwise specified. Absent.

[Embodiment]
<1: Overall configuration of switch module>
With reference to Fig.1 (a), the whole structure of the switch module 1 which concerns on embodiment which can apply this invention is demonstrated. FIG. 1A is a schematic cross-sectional view of the switch module 1 according to the present embodiment.

The switch module 1 according to the present embodiment is disposed to face a key substrate 8 having a key portion 7, and can be used for, for example, a 10-key substrate and a QWERTY key substrate in an electronic device such as a mobile phone and a notebook PC. is there. It can also be used for a touch panel or the like.

As shown in FIG. 1A, the switch module 1 includes an LED 2 as a light emitting element, a circuit board 6 having electrodes 11, a metal dome sheet 4 (electrode layer) having a metal dome 5 covering each electrode 11, and The light guide sheet 3 (light guide member) attached by the adhesion layer 10 is provided on the metal dome sheet 4. As the circuit board 6, an FPC board (FlexibleitPrinted Circuit) can be used. Further, between the LED 2 and the light guide sheet 3, there is provided a reflector 9 (reflecting member) that allows light emitted from the LED 2 to enter the light guide sheet 3 efficiently from the end of the LED 2. The end of the reflector 9 extends to a position that covers the upper surface of the end of the light sheet 3.

According to this configuration, the key top 7a moves downward in the drawing to press the metal dome sheet 4, thereby deforming the metal dome 5 and bringing the metal dome 5 and the electrode 11 into contact with each other. The electrode 11 is electrically connected, that is, the switch is switched from OFF to ON. In general, it is desirable for the switch module to transmit a sufficient click feeling to the user when the key unit is pressed from the viewpoint of operability. However, according to the present embodiment, the switch module has a certain strength. Since the switch is switched between ON and OFF by deformation of the metal dome 5 having the above, a sufficient click feeling can be transmitted to the user. Each metal dome 5 is integrally bonded to the metal dome sheet 4, and in the manufacturing process, the metal dome sheet 4 on which the metal dome 5 has been mounted is attached to the circuit board 6, so that the plurality of electrodes 11 are attached. On the other hand, the metal dome 5 can be attached with high accuracy and in a simple process.

<2: About the light guide sheet>
The light guide sheet 3 used in this embodiment will be described. In this embodiment, a urethane rubber sheet (thermosetting) having a thickness of 125 μm and a Shore hardness of 97 is used, but the material applicable as the light guide sheet 3 is not limited to this, A transparent sheet such as a polycarbonate film or a silicone rubber sheet may be used. Moreover, although the thickness of the light guide sheet 3 is not particularly limited, it can be said that the thickness is preferably 100 μm or more and 300 μm or less. The “transparent sheet” here does not necessarily mean colorless and transparent, and the light guide sheet 3 is limited to “colorless and transparent” as long as the light emitted from the LED 2 can be transmitted. is not.

In the present embodiment, since the light guide sheet 3 having such a small thickness is used, the switch module 1 can be reduced in size, and the click sensitivity described above can be further improved. In the following, on the surface of the light guide sheet 3, the surface facing the key substrate 8 (upper surface in the drawing) is referred to as “first surface 3 b”, and the surface facing the circuit substrate 6 (lower surface in the drawing). Is described as “second surface 3c”.

In the light guide sheet 3, the light incident on the light guide sheet 3 is scattered on the second surface 3 c, and the key portion 7 from inside the light guide sheet 3 by the scattered light (light L 2 in FIG. 1B). The light scattering processing that can illuminate is performed. Here, as the light scattering processing, dot printing (printing processing) with white ink (ink having light scattering properties) is performed by an ink jet printer, whereby white dots 3a are printed on the second surface 3c. (In this case, a white ink is used as the ink having a light scattering property, but an ink other than white may be used as long as it has a light scattering property.) The white dots 3 a are printed at positions corresponding to the key portions 7, whereby the light incident on the light guide sheet 3 from the LEDs 2 is scattered by the white dots 3 a, and the light guide sheet is scattered by the scattered light. It is possible to illuminate the key portion 7 from within 3. The dot density, shape, and the like of the white dots 3a are not particularly limited. For example, by increasing the number of white dots 3a in a region away from the LED 2 (region where light is attenuated and transmitted), Even the key portion 7 arranged in a region away from the LED 2 can be illuminated with a sufficient amount of light.

In addition, the form of light scattering processing is not limited to this, and is a form in which three-dimensional shape processing by mold processing, laser processing, or the like is performed at a predetermined position, and the light guide sheet 3 is formed with uneven shapes and prism shapes. There may be. Also in this case, similarly to the white dots 3a, it is possible to illuminate the key portion 7 suitably by scattering light by the portion subjected to the three-dimensional shape processing. The printing process (white dots 3a) is performed on the second surface 3c, but the three-dimensional shape process may be performed on the first surface 3b of the light guide sheet 3. Also in this case, the light is scattered in the three-dimensional shape processing applied to the first surface 3b, so that the light is transmitted from the first surface 3b in the direction of the key portion 7, and the key portion 7 is suitably illuminated. It becomes possible.

<3: About the reflector>
In this embodiment, the reflector 9 for making the light inject | emitted from LED2 inject into the light guide sheet 3 efficiently from the edge part of the light guide sheet 3 is provided. When the light guide sheet 3 having a small thickness is used as in the present embodiment, the thickness of the light guide sheet 3 is often thinner than the light emission area width of the LED 2. In order to make the light emitted from the LED 2 enter the light guide sheet 3 efficiently, it is effective to provide the reflector 9 between the LED 2 and the light guide sheet 3. In the present embodiment, the reflector 9 is provided at the end of the light guide sheet 3 so as to cover the first surface 3b in order to make light incident more efficiently, but the shape of the reflector 9 is particularly limited. It is not something. Moreover, as shown in the figure, a predetermined interval may be provided between the reflector 9 and the first surface 3b, or the reflector 9 and the first surface 3b may be brought into close contact with each other without providing an interval.

<4: How the light travels>
With reference to FIG.1 (b), the way of the light in the light guide sheet 3 in this embodiment is demonstrated. FIG.1 (b) is the schematic sectional drawing which expanded the vicinity of LED2 about the switch module 1 shown to Fig.1 (a).

The light emitted from the LED 2 is incident on the light guide sheet 3 from the end of the light guide sheet 3 by the reflector 9 (some light is directly incident on the light guide sheet 3 without going through the reflector 9). In the present embodiment, the first surface 3b and the second surface 3c of the light guide sheet 3 are both in contact with the air layer, and the difference in refractive index (assuming that the refractive index of the air layer is 1.0) Since the refractive index of the sheet 3 is about 1.45), the light traveling in the light guide sheet 3 repeats reflection on the first surface 3b and the second surface 3c as indicated by L1 and L2 in the figure. However, it proceeds toward the other end of the light guide sheet 3. If there is a white dot 3a on the optical path, the light is scattered at the white dot 3a, and the light exits from the light guide sheet 3 in the direction of the key portion 7 as indicated by L2 in the figure. Become. In addition, after being emitted from the LED 2, there is also light that passes through the adhesive layer 10 and enters the metal dome sheet 4, but this light is also reflected by the surface of the metal dome 5 and transmitted through the adhesive layer 10. The light enters the light guide sheet 3 again.

<5: Configuration for reducing light leakage>
With reference to FIG.1 (b) and FIG.1 (c), the structure which reduces the "light leakage" mentioned as the conventional subject is demonstrated. FIG. 1C is an enlarged view of the traveling pattern of the light L3 shown in FIG.

As described above, in the vicinity of the end portion of the light guide sheet 3 close to the LED 2, there is light that passes through the first surface 3b (the dotted line portion of L3 in FIG. 1B and FIG. 1C). In the configuration, the phenomenon that light leaks from the edge portion of the reflector is caused by such light. Therefore, in this embodiment, in order to solve this problem, the black sheet 12 (light absorbing property) is used to block the optical path of the light transmitted through the first surface 3b from the vicinity of the edge portion of the reflector 9 and reduce the amount of light leaking. (Member) is provided.

More specifically, the black sheet 12 is bonded to the upper surface of the reflector 9 (the surface opposite to the light guide sheet 3) to block the optical path of light that passes through the first surface 3b from the vicinity of the edge portion of the reflector 9. Thus, the end of the black sheet 12 is projected from the edge of the reflector 9.

According to such a configuration, the light L3 leaking from the edge portion of the reflector 9 can be absorbed by the black sheet 12, so that the amount of light leaking from the edge portion of the reflector 9 can be reduced. In addition, although the black sheet 12 is used here as a light absorptive member, you may use sheet materials other than black, and if it is a member which can absorb light suitably, members other than a sheet material ( For example, the structure which attaches a film etc. to the reflector 9 may be sufficient.

Further, when the black sheet 12 is attached to the upper surface of the reflector 9, it is easy to secure a space required for the attachment work, so that it is possible to improve productivity and reduce manufacturing costs. However, the mounting location of the black sheet 12 is not limited to this. That is, as shown in FIG. 2B, the black sheet 12 may be attached to the lower surface of the reflector 9 (the side on which the light guide sheet 3 is disposed). Even with such a configuration, it is possible to absorb light leaking from the vicinity of the edge portion of the reflector 9, so that the conventional problems can be solved. However, from the viewpoint of increasing the effective area of the reflector 9 (the area of the region used for light reflection), it is more preferable that the black sheet 12 is on the upper surface of the reflector 9.

Further, as another configuration for reducing light leakage, as shown in FIG. 2A, the reflector 9 is a surface opposed to the first surface 3 b and is first from the vicinity of the edge portion of the reflector 9. The print pattern 13 may be formed of light-absorbing ink on the optical path of light that passes through the surface 3b (position that closes the optical path). Examples of the light-absorbing ink include black ink, but may be gray or dark blue ink. Moreover, when forming the printing pattern 13, a normal inkjet printing system, a screen printing system, etc. are employable. Even with such a configuration, it is possible to absorb light leaking from the vicinity of the edge portion of the reflector 9.

<6: Position where the black sheet is provided>
The position where the black sheet 12 is provided will be described with reference to FIG. FIG. 3 is a top view of the switch module 1 according to the present embodiment, and is a diagram schematically showing, in particular, a position where the black sheet 12 is provided.

For example, as shown in FIGS. 3 (a), 3 (c), and 3 (e), the position where the black sheet 12 is provided is that the black sheet 12 is the reflector 9 when the switch module 1 is viewed from above. It may be a position hidden behind the reflector 9 (the lower surface of the reflector 9), and as shown in FIGS. 3B, 3D, and 3F, black is placed outside the reflector 9 (Y direction in the figure). The position where the sheet 12 protrudes may be used. Further, as described above, when the black sheet 12 projects outside the reflector 9, the black sheet 12 can be provided on both the upper surface and the lower surface of the reflector 9. Note that when the black sheet 12 protrudes to the outside of the reflector 9 (the protruding amount from the edge portion of the reflector 9 in the Y direction in the drawing) is “the protruding width of the (black sheet 12)”, the present inventor According to these intensive studies, it was found that if the “overhang width (mm)” is 0.3 mm or more and 0.7 mm or less, only light that causes light leakage can be absorbed more effectively.

In addition, the “illumination area” in FIGS. 3A to 3F indicates an area corresponding to the key portion 7, and the relative positional relationship between the “illumination area” and the LED 2 is taken into consideration. Thus, it is more effective to determine the position where the black sheet 12 (or the print pattern 13 using black ink) is provided. For example, as shown in FIGS. 3A and 3B, when the black sheet 12 is formed so that a slit is formed in front of the LED 2, the “illumination area” is prevented from being excessively lighted, and the lower side (Y Since more light from the LED 2 can be transmitted in the direction), even the key portion 7 located away from the LED 2 can be illuminated with a sufficient amount of light. Further, as shown in FIG. 3C and FIG. 3D, if the black sheet 12 is attached without providing a slit in front of the LED 2, it is possible to more surely prevent the “lighting area” from being excessively illuminated. In addition, as shown in FIGS. 3E and 3F, when there is an “illumination area” in front of the LED 2, if the black sheet 12 is attached in front of the LED 2, it is preferable that the “illumination area” is excessively illuminated. Can be suppressed. That is, the position of the black sheet 12 may be any position as long as only the light leaking from the “illumination area” can be absorbed.

<7: Black sheet shape>
In the present embodiment, as shown in FIGS. 3A to 3F, the black sheet 12 is formed in a rectangular shape. However, the shape of the black sheet 12 is not particularly limited. For example, it may be a shape that connects two surfaces having different areas as shown in FIGS. 3 (g) and 3 (h). Good. The black sheet 12 in the present embodiment is shaped so as to absorb only light leaking from the minute area, and the black sheet 12 is often shaped into a minute size so as not to absorb other light. However, in this case, it becomes difficult to attach the black sheet 12 to the reflector 9 with high positional accuracy.

Therefore, as shown in FIGS. 3 (g) and 3 (h), a black sheet 12 in which a light absorption surface 12a that blocks an optical path of light and a mounting surface 12c that is attached to the reflector 9 are connected by a connecting portion 12b. By using it, the mounting property can be improved. That is, here, the black sheet 12 is reflected by the reflector while effectively absorbing only the light to be absorbed by forming the mounting surface 12c so that the area of the mounting surface 12c is larger than the area of the light absorbing surface 12a. 9 is easy to install. Further, not only the mounting property of the black sheet 12 is improved, but also the adhesion area is increased, so that the black sheet 12 is hardly detached and the durability can be improved. In addition, as shown in FIG.2 (g), the light absorption surface 12a may exist in the position away from the edge part of the reflector 9. FIG.

<8: Verification experiment>
For each of (Comparative Example) and (Example 1) to (Example 5), a verification experiment was conducted to verify the effect of suppressing excessive illumination in the “illuminated area”. Hereinafter, the conditions and results of the verification experiment will be described with reference to FIGS. 4 (a) and 4 (b). FIG. 4A is a schematic diagram showing the arrangement of the “illumination area” (area corresponding to the key part) and the LED 2 used in the verification experiment, and FIG. 4B shows the (comparative example (left)) and It is the brightness | luminance contour map measured in each of (Example 1 (right)) (The upper side is the figure seen from the upper surface, The lower side is the figure represented in three dimensions.). Here, RISA-COLOR / ONEII manufactured by HI-LAND Co. was used as a luminance measuring device.

(Comparative example)
As a comparative example, the luminance (cd / m ² ) of the “illumination area” was measured when the black sheet 12 was not attached to the reflector 9 in the arrangement of the “illumination area” (key part) shown in FIG. . According to the earnest study by the inventors, among the plurality of “illuminated areas” shown in the figure, the phenomenon of “excessive light” has occurred in the “illuminated areas” (areas indicated by hatching) in the upper left and upper right. As a result, it has been confirmed that a satisfactory level of “brightness uniformity” has not been achieved. Therefore, the “illumination areas” in the upper left and upper right were targeted, and the luminance was compared between (Comparative Example) and (Example 1) to (Example 5). In (Comparative Example), the luminance of the “illuminated area” in the upper left is 39.6 cd / m ² , and the luminance of the “illuminated area” in the upper right is 37.2 cd / m ² . It was found that the brightness is higher than the brightness. However, locally, the upper left area near the LED 2 in the upper left “illumination area”, and the upper right area near the LED 2 in the upper right “illumination area”. , Each of which has been confirmed to be extremely bright.

Example 1
In Example 1, as shown in FIG. 4A, the black sheet 12 was attached to the reflector 9, the “overhang width (mm)” of the black sheet 12 was 0.5 mm, and the width in the X direction in the figure was 3 mm. A result of measuring the brightness at such a condition, (39.6cd ^{/ m} 2 in the comparative example) luminance 21.9cd / ^{m 2} of the "illuminated area" in the upper left, the luminance of the "illuminated area" in the upper right 22.9cd / m ² (37.2 cd / m ^{2 in the} comparative example) was confirmed to be significantly reduced. Further, in the other “illuminated areas”, the luminance decreased in the “illuminated area” close to the LED 2, while no significant decrease in luminance was observed in the “illuminated area” far from the LED 2. That is, it was found that “excessive light” can be suppressed and the requirement of “luminance uniformity” can be satisfied.

(Example 2)
In Example 2, the “overhang width (mm)” of the black sheet 12 was 0.7 mm, and the width in the X direction in the figure was the same as that of Example 1 (3 mm). A result of measuring the brightness at such a condition, (39.6cd ^{/ m} 2 in the comparative example) luminance 19.5cd / ^{m 2} of the "illuminated area" in the upper left, the luminance of the "illuminated area" in the upper right 20.5cd / m ² (37.2 cd / m ^{2 in the} comparative example) was confirmed to be significantly reduced. Further, in the other “illuminated areas”, the luminance decreased in the “illuminated area” close to the LED 2, while no significant decrease in luminance was observed in the “illuminated area” far from the LED 2. That is, it was found that “excessive light” can be suppressed and the requirement of “luminance uniformity” can be satisfied.

(Example 3)
In Example 3, the “overhang width (mm)” of the black sheet 12 was 0.1 mm, and the width in the X direction in the figure was the same as that of Example 1 (3 mm). A result of measuring the brightness at such a condition, (39.6cd ^{/ m} 2 in the comparative example) luminance 38.7cd / ^{m 2} of the "illuminated area" in the upper left, the luminance of the "illuminated area" in the upper right 36.2cd / m ² (37.2 cd / m ^{2 in the} comparative example) was confirmed to decrease. Further, in the other “illuminated areas”, the luminance decreased in the “illuminated area” close to the LED 2, while no significant luminance decrease was observed in the “illuminated area” far from the LED 2. That is, it was found that “excessive light” can be suppressed and the requirement of “luminance uniformity” can be satisfied.

Example 4
In Example 4, the “overhang width (mm)” of the black sheet 12 was 0.3 mm, and the width in the X direction in the figure was the same as that of Example 1 (3 mm). A result of measuring the brightness at such a condition, (39.6cd ^{/ m} 2 in the comparative example) luminance 26.0cd / ^{m 2} of the "illuminated area" in the upper left, the luminance of the "illuminated area" in the upper right 24.5cd / m ² (37.2 cd / m ^{2 in the} comparative example) was confirmed to be significantly reduced. Further, in the other “illuminated areas”, the luminance decreased in the “illuminated area” close to the LED 2, while no significant luminance decrease was observed in the “illuminated area” far from the LED 2. That is, it was found that “excessive light” can be suppressed and the requirement of “luminance uniformity” can be satisfied.

(Example 5)
In Example 5, the “overhang width (mm)” of the black sheet 12 was 1.0 mm, and the width in the X direction in the figure was the same as that of Example 1 (3 mm). A result of measuring the brightness at such a condition, (39.6cd ^{/ m} 2 in the comparative example) luminance 16.1cd / ^{m 2} of the "illuminated area" in the upper left, the luminance of the "illuminated area" in the upper right 17.2cd / m ² (37.2 cd / m ^{2 in the} comparative example) was confirmed to be significantly reduced. Further, in the other “illuminated areas”, the luminance decreased in the “illuminated area” close to the LED 2, while no significant decrease in luminance was observed in the “illuminated area” far from the LED 2. That is, it was found that “excessive light” can be suppressed and the requirement of “luminance uniformity” can be satisfied.

Next, FIG. 4B shows a luminance contour map of the “illumination area” in the upper left of FIG. 4A in (Comparative Example) and (Example 1). In FIG. 4B, the upper side shows the luminance contour map when the upper left “illumination area” is viewed from above, and the lower side shows the three-dimensional luminance contour map of the upper left “illumination area”. It is. As shown in the drawing, in (Comparative Example), the entire “illumination area” has high luminance, and in particular, the upper left region near the LED 2 shows extremely high luminance. On the other hand, in (Example), it turns out that the brightness | luminance has fallen as a whole. That is, it can be seen that by providing the black sheet 12, “too much light” can be reliably suppressed.

<9: Effects of this embodiment>
According to the switch module 1 according to the present embodiment, the following effects that cannot be obtained with the conventional configuration can be obtained.

(Restrictions on design of key part layout)
According to the switch module 1 which concerns on this embodiment, the light quantity which leaks from the edge part vicinity of the reflector 9 can be reduced by the above-mentioned structure. Therefore, in the conventional configuration, when the key part is arranged close to the LED, there is a problem that the key part in the vicinity of the LED is excessively lit due to the leaked light, and thereby the key part is arranged close to the LED. However, in the present embodiment, even if the key portion 7 is arranged close to the LED 2, such an excessive light problem does not occur. Therefore, the distance a shown in FIG. 1B (the distance between the key portion 7 closest to the LED 2 and the LED 2) can be reduced, that is, the key portion 7 can be arranged close to the LED 2. Design restrictions can be relaxed.

(About luminance uniformity)
According to the present embodiment, it is possible to suppress a phenomenon in which the key portion 7 disposed in the vicinity of the LED 2 is excessively bright as compared with the other key portions 7. Further, the black sheet 12 (or black ink printing pattern) provided on the reflector 9 is formed only on the optical path of the light leaking from the edge portion of the reflector 9, so that the key portion 7 is illuminated. Other light (for example, L1 and L2 in FIG. 1B) is not affected at all, and even the key portion 7 separated from the LED 2 can be illuminated with a sufficient amount of light. Therefore, it is possible to illuminate the plurality of key portions 7 arranged on the key substrate 8 with substantially uniform luminance, and it is possible to satisfy the requirement of “luminance uniformity”.

As described above, according to the present embodiment, in the switch module provided facing the key substrate, the amount of light leaking from the vicinity of the edge portion of the reflector toward the key portion is reduced, and the light traveling in the light guide member is used. It is possible to provide a switch module that can uniformly illuminate the key portion.

DESCRIPTION OF SYMBOLS 1 ... Switch module 2 ... LED 3 ... Light guide sheet 3a ... White dot 3b ... 1st surface 3c ... 2nd surface 4 ... Metal dome sheet 5 ... Metal dome 6 ... Circuit board 7 ... Key part 8 ... Key board 9 ... Reflector 10 ... Adhesive layer 11 ... Electrode 12 ... Black sheet 13 ... Print pattern

Claims

A switch module provided opposite to a key board having a key part,
A circuit board having an electrode layer formed on a surface facing the key board;
A light guide member provided between the key board and the circuit board;
A light source element that emits light;
A reflection member that causes light emitted from the light source element to enter the light guide member from an end of the light guide member;
With
A switch that can be turned on and off by moving the key portion with respect to the electrode layer, and that can illuminate the key portion from within the light guide member by light incident on the light guide member. In the module
The light guide member has a first surface facing the key substrate and a second surface on the opposite side and facing the circuit substrate, and the reflection member is a first surface at the end portion. It is provided so as to cover the surface,
In the reflection member,
A switch module comprising: a light-absorbing member that blocks an optical path of light that enters the light guide member and passes through the first surface from the vicinity of the edge portion of the reflecting member.
The light absorbing member is a sheet material having light absorption,
A light absorbing surface that blocks an optical path of light transmitted through the first surface from the vicinity of the edge portion of the reflecting member;
An attachment surface attached to the reflective member;
Have
The switch module according to claim 1, wherein an area of the attachment surface is formed to be larger than an area of the light absorption surface.
The sheet material is
The switch module according to claim 1, wherein the reflection member is attached to a surface opposite to a surface facing the light guide member.
A switch module provided opposite to a key board having a key part,
A circuit board having an electrode layer formed on a surface facing the key board;
A light guide member provided between the key board and the circuit board;
A light source element that emits light;
A reflection member that causes light emitted from the light source element to enter the light guide member from an end of the light guide member;
With
A switch that can be turned on and off by moving the key portion with respect to the electrode layer, and that can illuminate the key portion from within the light guide member by light incident on the light guide member. In the module
The light guide member has a first surface facing the key substrate and a second surface on the opposite side and facing the circuit substrate, and the reflection member is a first surface at the end portion. It is provided so as to cover the surface,
In the surface facing the first surface in the reflecting member,
A switch module, wherein a print pattern made of light-absorbing ink is formed on an optical path of light that enters the light guide member and passes through the first surface from the vicinity of the edge portion of the reflective member. .
In the light guide member,
Light scattering processing capable of scattering light incident on the light guide member has been performed, and the key portion from within the light guide member by light scattered in the portion subjected to the light scattering processing 5. The switch module according to claim 1, wherein the switch module can be illuminated.
The light scattering processing is
Print processing for printing light-scattering ink on the light guide member, or
Three-dimensional shape processing for forming a three-dimensional shape having light scattering properties on the light guide member;
The switch module according to claim 5, wherein:
In the light guide member,
The switch module according to any one of claims 1 to 6, wherein a sheet member having a light transmittance with a thickness of 100 µm to 300 µm is used.