1. Field of the Invention
The present invention relates to a switch for illuminating a knob.
2. Description of the Related Art
Japanese Unexamined Patent Application Publication No. 11-185558 discloses a switch which guides light rays from a light source to a knob via a light guiding member and a lens for illuminating the knob.
The switch is designed such that the incident light rays irradiated from the light source to the light guiding member are further irradiated to the lens from the lower portion at the substrate side. The incident light to the lens, which has been irradiated is guided to the knob so as to be illuminated.
The switch as disclosed above is designed to have the lens moved in association with the operation of the knob. The distance between the lens and the light guiding member for irradiating the light rays from the light source toward the lens varies as the knob is operated.
For example, when the knob is depressed to bring the lens into close to the light guiding member, the distance between the lens and the light guiding member is reduced to allow incidence of more light rays to the lens, thus increasing illumination luminance for the knob. When the lens is moved away from the light guiding member, the distance between the lens and the light guiding member is increased to reduce the amount of incident light rays to the lens, thus lowering illumination luminance for the knob.
Accordingly, the switch as disclosed in Japanese Unexamined Patent Application Publication No. 11-185558 changes the amount of incident light to the lens upon operation of the knob, thus largely changing the illumination luminance for the knob.
Accordingly, the switch designed to illuminate the knob is required not to largely change the illumination luminance for the knob upon its operation.
The present invention provides a switch which includes a knob used for operating a movable contact, a light source, and a lens for guiding a light ray from the light source to illuminate the knob. The lens is moved by operating the knob to change a distance between the lens and the light source. The lens is provided with a recess groove which intersects a light path of incident light to the lens. A protruding wall which protrudes toward the lens is formed on a substrate at a position corresponding to the recess groove. When the lens moves toward a direction to reduce the distance from the light source, the protruding wall is inserted into the recess groove by an amount corresponding to a displacement of the lens to shield the light path in accordance with the displacement.
According to the present invention, in the case where the lens is moved toward the direction to reduce the distance between the lens and the light source, the protruding wall is inserted into the recess groove of the lens by an amount corresponding to the displacement of the lens so as to shield the light path within the lens in accordance with the displacement.
The larger the amount of the incident light to the lens is increased as the lens is brought into close to the light source, the higher the level of shielding the light path by the protruding wall becomes. Meanwhile, the smaller the amount of the incident light to the lens is decreased as the lens is moved away from the light source, the lower the level of shielding the light path becomes. This makes it possible to keep the amount of the light for illuminating the knob substantially constant. As a result, large change in the illumination luminance for the knob may be prevented irrespective of change in the distance between the lens and the light source upon operation of the knob.
An embodiment according to the present invention will be described.
Referring to
The push knob 10 is a four-way switch which includes operation positions circumferentially arranged at an angular interval of 90°. For example, the operation positions to be depressed by the user for operating the equipment are located at regions a to d each designated with a “square” mark as illustrated in the drawing.
The push knob 10 includes a ring-shaped region a defined by the dotted lines as a surface illuminated by light rays irradiated from a light source disposed inside the switch 1.
The push knob 20 has an entire surface serving as the operation member, and a circular region β enclosed by the center dotted line serving as the surface to be illuminated. Both the push knobs 10 and 20 are formed of the light transmissive resin material.
Referring to
The push knob 10 is attached to the base 50 via a joint 80, and a lens 90 is disposed at the inner side of the joint 80 and interposed between the push knob 20 and the rubber contact sheet 60.
The upper case 30 has a rectangular top view, and an opening 31 formed at the center, through which upper surfaces of the push knobs 10 and 20 are exposed.
Referring to
An extending length h1 of the outer wall 13 is set to be shorter than an extending length h2 of the inner wall 12. A flange portion 14 which extends outward in the radial direction is formed at the lower end of the outer wall 13. The flange portion 14 is formed over an entire circumference of the outer wall 13 of the push knob 10 when seen from above. A lower surface 14a of the flange portion 14 serves as a depression surface with which a push rod 100 (to be described later) is depressed toward the pc board 70.
Referring to
The attachments 15 are oppositely positioned with respect to the opening 11 when seen from above. The push knob 10 is supported at the joint 80 by internally inserting an outer protrusion 82 of the joint 80 (to be described later) into a hole 15a of the attachment 15 outward in the radial direction so as to be swingable around the single axis (axis designated with line Y-Y of
As shown in
A length h3 of the peripheral wall 21 is set to be longer than the length h2 of the inner wall 12 of the push knob 10. The push knobs 10 and 20 are assembled while having the lower end of the inner wall 12 of the push knob 10 mounted on the upper surface of the flange portion 22 of the push knob 20 in the switch 1.
Three protrusions 23 which extend in the axial direction (vertical direction in
The protrusion 23 has a width corresponding to a guide groove 16 (see
The joint 80 with a ring-shaped top view is provided with outer protrusions 82 each with a columnar shape, protruding radially outward at opposite positions with respect to a center opening 81, specifically, at the lower end of the intersection between the line Y-Y of
Referring to
As illustrated in
The inner protrusions 83 are disposed at positions angularly offset at 90° in the circumferential direction of the joint 80 from the outer protrusion 82. The inner protrusion 83 is externally inserted into a hole 54a of a joint attachment 54 formed on the base 50 (to be described later) in the radial direction inward such that the joint 80 is swingably supported around the single axis (axis designated with line X-X of
As the swing axis (axis designated with line X-X of
Accordingly, the operation positions (square marks in the drawing) are set on the push knob 10 circumferentially at the angular interval of 90° based on the swinging direction.
The lens 90 includes a substantially circular main body 91 as a plan view, and an extending portion 92 which extends from the end of the main body 91 to the tangential direction.
As two-dot chain line in
As illustrated in
An upwardly extending columnar portion 93 with an outer diameter corresponding to the inner diameter of the peripheral wall 21 of the push knob 20 is formed at the center of the main body 91. The upper end surface of the columnar portion 93 serves as an output surface 93a for outputting the light toward the push knob 20 located above. A ring-shaped recess portion 94 is further formed to surround the columnar portion 93, which serves as a support portion for supporting the push knob 20 by allowing the flange portion 22 formed at the lower end of the push knob 20 to rest thereon.
A peripheral wall 95 which surrounds the ring-shaped recess portion 94 has its diameter reduced as it is brought upward from the position apart from a lower surface 91a at the side of the pc board 70 by a predetermined distance. The diameter is further reduced from the position which is brought over the output surface 93a of the columnar portion 93, resulting in output surfaces 95a and 95b for outputting the light toward the push knob 10.
A substantially columnar shaped opening 96 and a cylindrical support member 97 for surrounding the opening 96 are formed at the lower surface 91a of the main body 91.
A lower end 97a of the support member 97 downwardly extends to be lower than the lower surface 91a of the main body 91, and is supported at a depressing portion 65b (protrusion 65e) of a switch 65 (to be described later).
Referring to
As illustrated in
Referring to
Referring to
The embodiment is structured so that the recess groove 98 substantially intersects the light path H. In the state where the insertion portion 68a of the protruding wall 68 (to be described later, see
The light guided into the main body 91 after passing over the region of the recess groove 98 is distributed entirely on the main body 91 while reflecting therein, and is output from the output surfaces 93a, 95a and 95b (see
Referring to
As illustrated in
Push rod attachments 55 each outwardly extending in the radial direction are formed on the peripheral surface of the peripheral wall 53 of the base 50 circumferentially at the angular interval of 90°.
Referring to
The push rod 100 has the depression portion 100a mounted on a switch 64 to be described later, and an upper end of the shaft 100b abutted on a lower surface 14a of the flange portion 14 of the push knob 10, which is movably disposed up and down in the drawing.
As illustrated in
The light shielding wall 58 extends over an entire region above the extending portion 92 from the position just above the incident surface 92c of the extending portion 92 so as to be covered while avoiding the contact therewith. It is provided to shield the incident light to the incident surface 92c, which has leaked from the upper portion of the extending portion 92 so as not to directly irradiate the push knob 10.
As illustrated in
As illustrated in
The rubber contact sheet 60 includes a mount portion 62 mounted on the pc board 70, an upper wall 63 for connecting the mount portions 62, the switches 64, 65, and the protruding wall 68 (see
As illustrated in
Referring to
The peripheral wall 64c is formed to have its inner diameter increased as it is apart from the depression portion 64b, and its, leading end connected to the mount portion 62. The peripheral wall 64c allows the depression portion 64b to be disposed at a position above the pc board 70 apart therefrom by a predetermined distance, and has the movable contact 66 of the cylindrical portion 64a connected to the lower end of the depression portion 64b positioned apart from the fixed contact 71 on the pc board 70.
The switch 64 is disposed while allowing the depression portion 64b to urge the push rod 100 on the push knob 10.
The push knob 10 is depressed through operation of the user to push the push rod 100 toward the pc board 70. The push rod 100 then urges the switch 64 on the pc board 70.
At this time, the peripheral wall 64c is flexibly deformed to move the cylindrical portion 64a and the depression portion 64b toward the pc board 70. Then the switch 64 moves toward the pc board 70 until the movable contact 66 of the cylindrical portion 64a is in contact with the fixed contact 71 on the pc board 70.
When depression of the push knob 10 is finished, the restoring force of the peripheral wall 64c of the rubber contact sheet 60 formed of the material with excellent elasticity moves the depression portion 64b upward while lifting the push rod 100 such that the movable contact 66 formed at the lower end of the cylindrical portion 64a is apart from the fixed contact 71 on the pc board 70.
The switch 65 has a large difference from the switch 64 as described above only in the configuration of the depression portion 65b. The slope surface 65d which slants from the center to the circumferential edge portion is formed at the upper end of the depression portion 65b of the switch 65 when seen from above. The upper end of the switch 65 is formed to have a conical shape.
Four flexible protrusions 65e each extending upward are provided on the slope surface 65d at locations apart from the circumferential edge by a predetermined distance at predetermined intervals (see
The lower side of the lens 90 is supported only at the switch 65 which abuts the support member 97. The support member 97 supports the center of the main body 91 of the lens 90 when seen from above. The lens 90 is allowed to be slanted in an arbitrary direction at 360° with respect to the support member 97 as the center.
Referring to
Meanwhile, the push knob 10 is disposed in the state where the inner wall 12 is engaged with the recess portion 94 at the circumferential edge side of the lens 90. If any one of the operation positions a to d (see
For example, referring to
In the embodiment, the push knob 10 as the four-way switch is realized by arranging the switches 64 at the angular interval of 90° around the switch 65 at the center of the rubber contact sheet 60.
The switches 64 and 65 are provided at the positions corresponding to the fixed contacts 71, 72 on the pc board 70, respectively.
As illustrated in
The thin portion 67 is considerably thinner than the other portion of the rubber contact sheet 60, and integrally formed therewith while having the thickness which allows transmission of the light emitted from the light source 73. The rubber contact sheet 60 includes the protruding wall 68 at the position corresponding to the recess groove 98 of the lens 90.
The protruding wall 68 protrudes from the upper wall 63 of the rubber contact sheet 60 toward the lens 90, and includes the plate like insertion portion 68a to be inserted into the recess groove 98, and a support portion 68b for connecting the insertion portion 68a to the upper wall 63 so that the insertion portion 68a is supported above the pc board 70 at the side of the lens 90.
The insertion portion 68a extends along the recess groove 98 of the lens 90 when seen from above at the side of the lens 90, and both ends in the longitudinal direction are formed to have curved surfaces (see
As illustrated in
The insertion portion 68a and the support portion 68b are connected at the position above the upper wall 63 at the side of the lens 90. The insertion portion 68a is movably held by the support portions 68b above the pc board 70 at the side of the lens 90.
In the case where the lens 90 moves toward the pc board 70 upon operation of the push knobs 10 and 20, and is interfered with the insertion portion 68a, the lens 90 is allowed to move without interference by easily displacing the insertion portion 68a while deforming the support portion 68b.
The height ha from the upper wall 63 to the upper end of the protruding wall 68 corresponds to the height at which the protruding wall 68 is positioned outside the recess groove 98 in the case where the lens 90 is at a normal position where it is not depressed by the push knobs 10 and 20 toward the pc board 70.
The height hb of the insertion portion 68a is set to the dimension of height which causes the insertion portion 68a to be abutted on a bottom 98a of the recess groove 98 when the lens 90 is at the working position under pressure by the push knob 10 against the pc board 70 (slightly longer than the depth dimension hg of the recess groove 98) for ensuring shielding of the light path across the recess groove 98 inside the lens 90.
The thickness and width of the insertion portion 68a are set in the range which allows insertion into the recess groove 98 for shielding the intersecting light path.
As illustrated in
The fixed contact 71 is formed on the pc board 70 just below each of the four operation positions a to d (see
A not shown connector terminal connected to the pc board 70 is capable of identifying as to which portion among the push knob 20 and operation positions of a to d of the push knob 10 has been operated, and the time taken for the operation.
Only a single unit of the light source 73 is formed on the pc board 70 for irradiating light rays toward the light receiving surface of the lens 90 located just above the light source 73.
An operation of the protruding wall 68 in the thus structured switch 1 will be described.
In the case where the push knobs 10 and 20 are not operated, and the lens 90 is at the normal position, the insertion portion 68a of the protruding wall 68 is positioned outside the recess groove 98 of the lens 90 as illustrated in
The incident light from the light source 73 to the lens 90 from the incident surface 92c is reflected on the slope surface 92d, and passes the recess groove 98 so as to be guided into the main body 91 of the lens 90. It is then irradiated from the output surfaces 93a, 95a and 95b (see
That is, all the incident light rays to the lens 90 are used for illuminating the push knobs 10 and 20.
In the case where the push knobs 10 and 20 are operated, and the lens 90 moves from the position illustrated in
As the lens 90 moves toward the pc board 70, the distance between the incident surface 92c of the lens 90 and the light source 73 on the pc board 70 is reduced. The amount of the incident light to the lens 90 from the incident surface 92c may be increased by the degree corresponding to the reduced distance.
In the embodiment, the insertion amount of the insertion portion 68a into the recess groove 98 is increased accompanied with increase in the amount of the incident light to the lens 90 resulting from its movement toward the pc board 70, thus increasing the light shielding level at the portion of the light path H which passes through the recess groove 98.
In the case where the push knob 10 is fully pushed to move the lens 90 to the operation position closest to the pc board 70, the light at the position of the light path H, which does not pass through the recess groove 98 is only used for illuminating the push knobs 10 and 20.
In the embodiment, accompanied with the movement of the lens 90 to increase amount of the incident light thereto, the light ray used for illuminating the push knobs 10 and 20 is narrowed. Then the depth and range of the recess groove 98, and the insertion amount of the insertion portion 68a into the recess groove 98 are determined so that the push knobs 10 and 20 are illuminated with the light by substantially the same amount in the case where the lens 90 is not moved.
This makes it possible to favorably prevent intensity for illuminating the push knobs 10 and 20 from largely fluctuating owing to the change in the distance between the incident surface 92c of the lens 90 and the light source 73 upon operation of the push knobs 10 and 20.
The push knobs 10 or 20 in the embodiment correspond to the knob according to the present invention, and the rubber contact sheet 60 corresponds to the retainer member according to the present invention.
As described above, the switch 1 in the embodiment is provided with the push knobs 10, 20 for operating the movable contact 66, the light source 73 disposed on the pc board 70, and the lens 90 which guides the light ray from the light source 73 toward the push knobs 10, 20 so as to be illuminated, and structured to move the lens 90 by operating the push knobs 10, 20 to change the distance between the incident surface 92c of the lens 90 and the light source 73. The lens 90 is provided with the recess groove 98 which intersects the light path H of the incident light to the lens 90. The protruding wall 68 which protrudes toward the lens 90 is formed on the pc board 70 at the position corresponding to the recess groove 98. When the lens 90 moves toward the direction to reduce the distance between the incident surface 92c and the light source 73, the insertion portion 68a of the protruding wall 68 is inserted into the recess groove 98 by the amount corresponding to the displacement of the lens 90 such that the light path H is shielded by the insertion portion 68a in accordance with the displacement of the lens 90.
As the amount of the incident light to the lens 90 which moves toward the direction to reduce the distance between the incident surface 92c and the light source 73 is increased more, the insertion amount of the insertion portion 68a into the recess groove 98 becomes large, thus increasing the level for shielding the light path H by the insertion portion 68a. Meanwhile, as the amount of the incident light to the lens 90 which moves toward the direction to increase the distance between the incident surface 92c and the light source 73 is decreased, the insertion amount of the insertion portion 68a into the recess groove 98 becomes small, thus reducing the level for shielding the light path H by the insertion portion 68a.
The above-described structure is capable of keeping the amount of the light for illuminating the push knobs 10, 20 substantially constant irrespective of the change in the distance between the incident surface 92c and the light source 73. This may prevent large change in the illumination luminance for the push knobs 10, 20 caused by the change in the distance between the incident surface 92c of the lens 90 and the light source 73 upon operation of the push knobs 10, 20.
The lower surface 91a of the lens 90 at the side of the pc board 70 is supported at the rubber contact sheet 60 for movably holding the movable contact 66 above the fixed contact 71 on the pc board 70 to be close thereto or away therefrom. The push knobs 10 and 20 are mounted on the lens 90.
When the push knobs 10 and 20 are operated and depressed toward the pc board 70, the lens 90 moves toward the pc board 70 together with the push knobs 10 and 20. Each displacement of the push knobs 10 and 20 directly reflects the displacement of the lens 90. Accordingly, the shielding level of the light path H by the protruding wall 68 may be set to the appropriate value in accordance with the actual displacement (operation amount) of the push knobs 10 and 20.
The protruding wall 68 is integrally formed with the rubber contact sheet 60 which constitutes the switches 64 and 65 for detecting operations of the push knobs 10 and 20.
Compared with the case where the protruding wall 68 is provided separately from the rubber contact sheet 60, the protruding wall 68 in the embodiment may be disposed with high positional accuracy. The rubber contact sheet 60 having the protruding wall 68 and the switches 64, 65 already formed may be obtained, thus eliminating the manufacturing steps, and contributing to the cost reduction for manufacturing the switch 1.
The protruding wall 68 is provided with the insertion portion 68a configured to be mated with the recess groove 98, and the support portion 68b so as to be movably supported above the pc board 70 at the side of the lens 90. It is formed of the rubber material with excellent flexibility and elasticity, and integrally formed with the rubber contact sheet 60.
When the push knobs 10, 20 are operated to depress the lens 90, movement of the lens 90 is not interfered with the insertion portion 68a which is depressed by the lens 90 toward the pc board 70.
The use of the material with excellent flexibility and elasticity for forming the protruding wall 68 may protect the protruding wall 68 from being broken due to fatigue resulting from repetitive interference caused by the moving lens 90.
The embodiment explains the case where the light source 73 is directly attached to the pc board 70. However, any structure may be formed so long as the incident light to the lens 90 from the light source 73 is guided to the push knobs 10 and 20. For example, the light source may be provided at the position away from the pc board through connection with the lead wire extending from the pc board terminal. Alternatively, the light source may be attached to the terminal block having the conductive plate conducted to the terminal or the fixed contact insert molded using the insulating resin instead of the use of the pc board.
Number | Date | Country | Kind |
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2009-104362 | Apr 2009 | JP | national |