JP2006344609A - Key switch and keyboard having the same - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To realize a key switch of a low height making use of a link mechanism. <P>SOLUTION: A key top 21B has bearing parts 21B-11, 21B-12 on its underside. A housing 25B has sliding guide parts 25B-11, 25B-12 on its upper surface. In a first link 31B and a second link 32B, rotating axis parts 31-4, 31-5 are held rotatably in the bearing part 21B-11, 21B-12 of each key top 21B and fan-shaped gears 31-6, 31-7 are engaged to make a V-shape, and sliding axis parts 31B-3a, 31B-3b are coupled each slidably with the sliding guide parts 25B-11, 25B-12. When the key top 21B is pressed down, the sliding axis parts 31B-3a, 31B-3b are shifted in directions of X1, X2 and the first and second links 31B, 32B will rotate symmetrically in a horizontal direction. <P>COPYRIGHT: (C)2007,JPO&INPIT

Description

  The present invention relates to a key switch and a keyboard having the key switch, and more particularly to a key switch applied to a low-profile keyboard applied to a notebook personal computer and a keyboard having the key switch.

  FIG. 27 shows a part of a conventional key switch 10. FIG. 4A shows a state before the operation, and FIG. 4B shows a state when the push-down operation is performed.

  The key switch 10 includes a key top 11 that is pushed down, a membrane sheet 13 having a membrane switch 12, a support panel 14 that supports the membrane sheet 13, and a support panel 14 that is fixed on the membrane sheet 13. It has a housing 15 and a rubber actuator 16 that is pushed and deformed by the key top 11 during operation to close the membrane switch 12 by pushing it. The housing 15 has a cylindrical portion 15a. The key top 11 has a cylindrical portion 11a, and the cylindrical portion 11a is slidably fitted into the cylindrical portion 15a. When the key top 11 is pushed down with the fingertip 19, as shown in FIG. 27B, the key top 11 is moved down in the Z2 direction (FIG. 27A) while being guided by the cylindrical portion 15a, and the actuator 16 is moved. It is deformed so that it is crushed, and the membrane switch 12 is pushed to close it.

  When the fingertip 19 is separated from the key top 11, the key top 11 is pushed up by the elastic force of the rubber actuator 16, and the original state shown in FIG.

However, the conventional key switch 10 has the following two problems.
(1) The height is not low enough (height dimension H1 cannot be reduced).

  The height dimension H1 of the key switch 10 includes a dimension H2 from the bottom surface of the support panel 14 to the upper surface 15b of the housing 15, a height dimension H3 of the cylindrical portion 15a, and the key top 11 above the upper end of the cylindrical portion 15a. This is a dimension obtained by adding the height dimension H4 of the space 18 corresponding to the pressing stroke S and the thickness dimension t1 of the main body 11b of the key top 11.

  Here, the cylindrical portion 15a guides the cylindrical portion 11a of the key top 11 moving downward in the Z2 direction, the extending direction is the Z1 and Z2 directions, and the length is stably supported by the key top 11. 3-4 mm is required to be done.

  Thus, on the upper surface of the housing 15, the length 15 in the Z1 and Z2 directions is 3 to 4 mm. Therefore, the height dimension H1 of the key switch 10 is about 11 mm, which is a low profile. It was not enough.

In order for the key switch 10 to have a normal operation feeling, the pressing stroke S of the key top 11 requires about 3 mm. Therefore, the dimension H4 is a little over 3 mm.
(2) Sensitive to dust.

  The gap 17 between the cylindrical portion 15a and the cylindrical portion 11a is set small so that the key top 11 can smoothly move down even when the corner portion of the key top 11 is pressed. The direction in which the cylinder portion 11a moves is the axial direction of the cylinder portion 15a. For this reason, when dust intrudes into the gap 17, there is a possibility that the sliding motion may not be smoothly performed. If the sliding movement of the cylindrical portion 11a is not smoothly performed, the key switch 10 will malfunction.

  Therefore, an object of the present invention is to provide a key switch that solves the above-described problems and a keyboard having the key switch.

The invention of claim 1 includes a key top that is depressed,
A housing disposed below the key top;
An actuator which is located below the key top and is pressed and elastically deformed when the key top is pushed down to close a contact point and apply a pushing force to the key top;
The key comprises a first link and a second link provided between the housing and the key top, and the key top that has been pushed down is lowered, and the key top is raised by an elastic restoring actuator. In a key switch having a link mechanism for supporting a top with respect to the housing,
The key top is configured to have a bearing portion on the lower surface thereof,
The housing is configured to have, on the upper surface thereof, a sliding guide portion that slides and guides in a direction perpendicular to a direction in which the key top is pushed down.
Each of the first and second links has a sliding shaft portion at one end of the arm portion, and a rotation transmission means portion and a rotation shaft portion at the other end of the arm portion,
In the link mechanism, the first link and the second link are slidably fitted to the slide guide portion and supported by the housing, and the rotation transmission means portion. And the pivot shaft portion is pivotably engaged with the bearing portion of the key top, and the arm portion of the first link and the second link are engaged with each other. The arm portions are arranged in an inverted V shape without crossing each other.

  Since the first link and the second link constitute a link mechanism in which the respective arm portions do not cross each other and are arranged in an inverted V shape, and the key top is supported by the link mechanism, the key switch Can be realized.

  Next, an embodiment of the present invention will be described.

  1 is an exploded view of a key switch 20 according to a first embodiment of the present invention. FIGS. 3 (A) and 4 (A) show a state before operation, and FIG. 3 (C), FIG. 4 (B), FIG. 5 shows a state when the push-down operation is performed. FIG. 2 is a plan view showing the key switch 20 through the key top.

  The key switch 20 is of a single piece type, and a PET film membrane sheet 23 (FIG. 5) having a key top 21 to be pushed down and a membrane switch 22 having two contact points facing each other. A support panel 24 for supporting the membrane sheet 23 (FIG. 3), a housing 25 fixed to the support panel 24 and provided on the membrane sheet 23, and pressed by the key top 21 during operation to be deformed and the membrane switch A rubber actuator 26 that pushes 22 and closes it, and a link mechanism 27 provided between the housing 25 and the key top 21 are provided. As will be described later, the link mechanism 27 acts to lower the height position of the key top 21 in a state where the key top 21 secures a necessary stroke.

  The membrane switch 22 includes a contact printed on the membrane sheet 23 (FIG. 5). The housing 25 and the support panel 24 are fixed by screwing or caulking.

  The link mechanism 27 has a structure in which a first link 31 and a second link 32 each having a substantially U shape are combined in a substantially V shape.

  The first link 31 is made of polyacetal resin. As shown in FIGS. 7A to 7C, the first link 31 includes a pair of parallel elongated first arm portions 31-1 and 31-2, and a slide. It has a moving shaft portion 31-3, rotating shaft portions 31-4 and 31-5, and sector gear portions 31-6 and 31-7. The sliding shaft portion 31-3 connects between the first ends 31-1a and 31-2a of the first arm portions 31-1 and 31-2, whereby the first link 31 is substantially U-shaped. It has a shape. The rotation shaft portions 31-4 and 31-5 protrude outward from the other ends 31-1b and 31-2b of the first arm portions 31-1 and 31-2. The sector gear portions 31-6 and 31-7 are arranged at the other ends 31-1b and 31-2b of the first arm portions 31-1 and 31-2 around the rotation shaft portions 31-4 and 31-5. It is formed at the site. Here, as shown in FIG. 3C, since the angle α at which the first link 31 rotates is limited to about 45 degrees, the sector gear portions 31-6 and 31-7 are also sector-shaped apex angles. β is formed only within an angular range of about 90 degrees. The configuration in which the angular range of the sector gear portions 31-6 and 31-7 is limited to about 90 degrees contributes to a reduction in the height of the key switch 20, as will be described later. Further, the sector gear portions 31-6 and 31-7 constitute a rotation transmission means portion according to claim 10.

  The gear portion 31-6 has three teeth 40, 41, and 42 having a pitch circle diameter of 3 mm, a module of 0.3, and a pitch of P1. There are tooth spaces 43 and 44 between adjacent teeth. The other gear portion 31-7 also has three teeth 50, 51, 52 having a pitch circle diameter of 3 mm, a module of 0.3, and a pitch of P1, similar to the gear portion 31-6. Between adjacent teeth, there are tooth gaps 53 and 54. As can be seen from FIGS. 7A and 7C, when viewed from the direction of the arrow A, the gear portion 31-7 is provided with a 1/2 pitch shift in the arrow C direction with respect to the gear portion 31-6. This is because the parts of the first link 31 and the second link 32 are shared.

  The second link 32 is the same component as the first link 31 and is simply changed in direction. In FIG. 1, for the second link 32, each part is denoted by a reference numeral affixed to the reference numeral indicating each part of the first link 31, and description thereof is omitted.

  As shown in FIG. 1, the housing 25 has a rectangular plate-shaped main body 25-1, a circular opening 25-2, elongated openings 25-3 and 25-4, and ribs 25-5 and 25-6. It has a structure. The circular opening 25-2 is located at the center of the rectangular plate-shaped main body 25-1, receives the actuator 26, and restricts the position thereof. The ribs 25-5 and 25-6 are located near the ends of the rectangular plate-shaped main body portion 25-1 in the Y2 and Y1 directions, and protrude toward the upper surface of the rectangular plate-shaped main body portion 25-1 so as to be in the X1 and X2 directions. It extends to. Two bearing holes 25-5-1, 25-5-2, 25-6-1 and 25-6-2 are formed to face the ribs 25-5 and 25-6, respectively. The elongated openings 25-3 and 25-4 are formed along the insides of the ribs 25-5 and 25-6, respectively. As shown in FIG. 5, the elongated openings 25-3 and 25-4 accommodate part of the gear portions 31-6 and 31-7, and the rotary shaft portion 31-4 of the first link 31. To lower the position.

  As shown in FIG. 6 as well, the key top 21 has a flat shape. The key top body 21-1 has a flat space on the lower surface side, and one circular shape protrudes from the lower surface of the key top body 21-1. It consists of a convex part 21-2, four sliding guide parts 21-3 to 21-6, and two stopper parts 21-7 and 21-8. The key top body 21-1 has a flat shape, and has a flat space 21-1a (FIGS. 1 and 6) on the lower surface side. The depth b of the flat space 21-1a is set to a dimension that can accommodate the first and second links 31, 32 having an opening angle of 180 degrees. The circular convex portion 21-2, the four sliding guide portions 21-3 to 21-6, and the two stopper portions 21-7 and 21-8 are all located in the flat space 21-1a. The circular convex portion 21-2 is located at the center of the key top body 21-1 and pushes the actuator 26.

  As shown in FIG. 6, the four sliding guide portions 21-3 to 21-6 are provided in a portion around the circular convex portion 21-2. The sliding guide portion 21-3 includes a column portion 21-3a protruding from the lower surface of the key top body 21-1, and an arm portion 21-3b extending in the X1 direction from the column portion 21-3a. A sliding guide path 21-3c (FIGS. 2B and 6) is formed between the lower surface of the key top body 21-1 and the arm portion 21-3b. The column part 21-3a receives the sliding shaft part 31-3 (FIG. 2) of the first link 31, and functions as a stopper when the key top body 21-1 rises in the Z1 direction (FIG. 6). . The other sliding guide portions 21-4, 21-5, and 21-6 have the same structure as the sliding guide portion 21-3. The arm portion 21-4b (FIG. 6) extends in the X1 direction, and the arm portions 21-5b and 21-6b extend in the X2 direction. Here, the sliding guide path 21-3c exists in the XY plane perpendicular to the Z2 direction that is the key-down direction of the key top 21, and the sliding shaft portion 31 of the first link 31 is present. -3 moves not in the ZX plane but in the XY plane when the key top 21 moves up and down. With this configuration, the height dimension H13 (see FIG. 3A) occupied by the sliding guide portions 21-3 to 21-6 may be small. This contributes to a reduction in the height of the key switch 20.

  The stopper portion 21-7 (FIG. 6) is provided at the X1-direction end of the key top body 21-1, and the stopper portion 21-8 is provided at the X2-direction end of the key top body 21-1. Further, as shown in FIG. 2, the dimension e in the X1 and X2 directions between the tips of the arm portions 21-3b and 21-4b and the stopper portion 21-7 is the diameter d of the sliding shaft portion 31-3. The dimensions are slightly smaller. This is to facilitate the assembly of the key switch 10. The dimension in the X1, X2 direction between the tip of the arm part 21-5b, 21-6b and the stopper part 21-8 is also set as the dimension e.

  Moreover, the recessed parts 21-1a (FIG. 5) and 21-1b (FIG. 5, FIG. 6) are formed in the Y1, Y2 end side among the lower surfaces of the keytop main body 21-1. This is because a part of the gear portions 31-6 and 31-7 is accommodated when the key top 21 is pushed down (FIG. 5).

  Next, the configuration of the main part of the key switch 20 will be described with reference to FIGS.

  As shown in FIG. 1, FIG. 3 (A), FIG. 4 (A), and FIG. 2, the first link 31 has rotating shaft portions 31-4 and 31-5 connected to ribs 25-5 and 25-6. It is pivotally supported by the bearing holes 25-5-1 and 25-6-1. In the second link 32, the rotation shaft portions 31-5a and 31-4a are pivotally supported by the bearing holes 25-5-2 and 25-6-2 of the ribs 25-5 and 25-6. The gear portion 31-6 of the first link 31 meshes with the gear portion 31-7a of the second link 32 (FIG. 5), and the gear portion 31-7 of the first link 31 is the second link. It meshes with 32 gear portions 31-6a. The first link 31 and the second link 32 are symmetrical with respect to the YZ plane passing through the center between the bearing hole 25-5-1 (FIG. 1) and the bearing hole 25-5-2 (FIG. 1). Thus, as shown in FIG. 3A, a substantially V shape having an opening angle γ of about 70 degrees is formed.

  The sliding shaft portion 31-3 of the first link 31 slides in the X1 and X2 directions on the sliding guide path 21-3c (FIG. 3C) at a portion near the first arm portion 31-1. A portion close to another first arm portion 31-2 is slidably fitted in the sliding guide path 21-4c (FIG. 6) in the same direction. The sliding shaft portion 31-3a of the second link 32 slides in the X1 and X2 directions along the sliding guide path 21-5c (FIG. 3 (B)) near the second arm portion 32-1. It fits so that the site | part near another 2nd arm part 32-2 is fitted to the sliding guide path 21-6c so that sliding is possible in the same direction. The key top 21 includes first and second sliding guide portions 21-3, 21-4, 21-5, 21-6 that form a substantially V shape with an opening angle γ of about 70 degrees. The slide shafts 31-3 and 31-3 a of the links 31 and 32 are fitted and supported on the first and second links 31 and 32. A substantially cylindrical rubber actuator 26 (FIG. 4) is fitted into the circular opening 25-2 of the housing 25 and positioned and is placed on the membrane sheet 23. The top surface of the actuator 26 pushes up the key top 21. The first and second links 31 and 32 are in a standing state.

  The height position Q1 of the key top 21 is such that the sliding shaft portions 31-3 and 31-3a are the ends closer to the center of the key top 21 of the sliding guide portions 21-3 to 21-6, that is, the column portion 21. -3a to 21-6a.

  Next, the operation of the key switch 20 when the key top 21 is operated will be described.

  When the key top 21 is pushed down with the fingertip 19, the lower surface of the keytop body 21-1 is moved to the sliding shaft portion 31-3 of the first link 31 according to the portion of the keytop 21 pressed with the fingertip 19, or The sliding shaft portion 32-3 of the second link 32 is pushed. When the X1 side of the key top 21 is pressed, the sliding shaft portion 31-3 of the first link 31 is pressed, and when the X2 side of the key top 21 is pressed, the second The sliding shaft portion 32-3 of the link 32 is pushed. When the central portion of the key top 21 is pressed, the sliding shaft portion 31-3 of the first link 31 and the sliding shaft portion 31-3a of the second link 32 are pressed together.

  Here, a case where the center portion P1 of the key top 21 is pressed in FIG. 3A will be described. When a force F is applied to the central portion P1, the lower surface of the key top body 21-1 pushes the sliding shaft portions 31-3 and 31-3a simultaneously, the first link 31 rotates in the CC direction, and the second The link 32 rotates in the C direction, and the key top 21 descends in the Z2 direction. As shown in FIG. 3 (B), the key top 21 has links 31 and 32 in which the slide shaft portion 31-3 slides in the X1 direction in the slide guide path 21-3c. 31-3a rotates while sliding in the X2 direction in the sliding guide path 21-5c. That is, the key top 21 is supported by the first and second links 31 and 32 while the sliding guide paths 21-3c and 21-5c are supported by the sliding shaft portions 31-3 and 31-3a. It descends while being supported and maintaining a horizontal posture. The key top 21 is pushed down to the lowest position shown in FIG. 3 (C), FIG. 4 (B), and FIG. When the key top 21 is pushed down, as shown in FIG. 4B, the rubber actuator 26 is deformed so as to be crushed, and the membrane switch 22 is pushed to close it. The first and second links 31 and 32 rotate by an angle α (about 50 degrees), open until the opening angle becomes about 180 degrees, become substantially straight, and the flat space 21 of the key top 21. -1a. A part of the sector gear portions 31-6 and 32-7 is accommodated in the recesses 21-1a and 21-1b on the lower surface of the key top body 21-1, as shown in FIGS. .

  When the fingertip 19 is separated from the key top 21, the key top 21 is pushed up (biased) in the Z1 direction by the elastic force of the rubber actuator 26. The first and second links 31 and 32 are rotated so as to stand up contrary to the above, and the key top 21 is supported by the first and second links 31 and 32 and is lifted while maintaining a horizontal posture. To do.

  Next, a case where the corner is pressed will be described.

  In FIG. 3A, when the portion P2 closer to X1 in the key top 21 is pressed, the lower surface of the key top body 21-1 presses the sliding shaft portion 31-3. The link 31 rotates in the CC direction, and this rotation is transmitted to the second link 32 via the sector gear portions 31-6 and 31-7a, and the second link 32 is the first link in the C direction. It rotates at the same speed as 31. Similarly to the above case, the key top 21 is supported by the first and second links 31 and 32, and descends in the Z1 direction while maintaining a horizontal posture without being inclined at all.

  3A, when the portion P3 closer to X2 in the key top 21 is pressed, the lower surface of the key top body 21-1 presses the sliding shaft portion 31-3a. The link 32 rotates in the C direction, and this rotation is transmitted to the first link 31 via the sector gear portions 31-7a and 31-6, and the first link 31 is the second link in the CC direction. It rotates at the same speed as 32. Similarly to the above case, the key top 21 is supported by the first and second links 31 and 32, and descends in the Z1 direction while maintaining a horizontal posture without being inclined at all.

  Note that in the sector gear portions 31-6 and 31-7a, the sliding does not occur a little, the rotation is reliably transmitted, and even after the key operation is repeated many times, the first link 31 and the first link 31 The two links 32 rotate at the same speed, that is, rotate symmetrically.

  Further, as shown in FIG. 3C, at the position Q2 where the key top 21 is most depressed, the four sliding guide portions 21-3 to 21-6 and the two stopper portions 21-7 and 21-8 are housings. It is regulated by hitting the upper surface of 25. For this reason, even when the key top 51 is strongly pressed down, the membrane switch 22 is not excessively pressed and the membrane switch 22 is protected.

  When the key top 21 descends and ascends, the sliding shaft portions 31-3 and 31-3a move in the direction orthogonal to the axis line, and X1, X2 in the sliding guide paths 21-3c and 21-5c Slide in the direction. Therefore, even if dust enters the sliding guide paths 21-3c and 21-5c, the dust that has entered is pushed away by the sliding shaft portions 31-3 and 31-3a, and the sliding shaft portion 31- 3, 31-3a is not disturbed at all, and the sliding shaft portions 31-3, 31-3a slide smoothly in the sliding guide paths 21-3c, 21-5c. Therefore, the key switch 20 operates normally and is resistant to dust.

  Here, the reason why the key switch 20 having the above structure has a normal operation feeling and is low in height (the height dimension H11 is small) will be described.

  As shown in FIG. 3A, the height dimension H11 of the key switch 20 is equal to the dimension H12 from the bottom surface of the support panel 24 to the upper surface 25-1a of the main body portion 25-1 of the housing 25, and the sliding guide portion 21. The dimension obtained by adding the height dimension H13 of −3, 21-5, the height dimension H14 of the space 59 corresponding to the pressing stroke S of the key top 21, and the thickness dimension t2 of the main body 21-1 of the key top 21 It is.

  Here, the height dimension H14 is slightly over 3 mm, which is the same as the height dimension H4 in FIG. Therefore, the pressing stroke S of the key top 21 is about 3 mm, and the key switch 20 has a normal operation feeling.

  The dimension H12 is the same as the dimension H2 in FIG. The dimension t2 is the same as the dimension t1 in FIG.

  The sliding guide portions 21-3 and 21-5 correspond to the cylindrical portion 15a in FIG. The extending directions of the sliding guide portions 21-3 and 21-5 are X1 and X2, and the sliding guide portions 21-3 and 21-5 have a flat shape. Therefore, the height dimension H13 is approximately 2.5 mm smaller than the height dimension H3 of the cylindrical portion 15a in FIG.

  Therefore, the height dimension H11 of the key switch 20 is about 8.5 mm, which is about 2.5 mm smaller than the height dimension H1 of the key switch 10 of FIG.

  For this reason, the key switch 20 has a normal operation feeling and is shorter than a conventional key switch.

  Next, assembly of the key switch 20 shown in FIGS. 1 and 3A will be described with reference to FIGS. 8 and 9A to 9C.

  As shown in FIG. 8, the upper part of the key switch 20 includes (1) a step 70 for incorporating the first link 31 into the housing 25, and (2) incorporating the second link 32 into the housing 25. Assembling is performed in the order of a step 71 for combining with 31, (3) a step 72 for opening the first link 31 and the second link 32, and (4) a step 73 for attaching the key top 21 to the link mechanism 27.

  About step 70.

  First, as shown in FIG. 9A, a first link 31 and a second link 32 (which are the same parts as the first link 31) are prepared. In the posture, the tips of the pair of parallel elongated first arms 31-1, 31-2 are slightly narrowed as shown by the two-dot chain line in FIG. 7B, and the ribs 25-5, 25- 6 and inserting the shafts 6 to release the recesses, the rotating shaft portions 31-4 and 31-5 are fitted in the bearing holes 25-5-1, 25-6-1.

  About step 71.

  Next, the second link 32 is placed in a vertical posture similar to the first link 31, and the rotation shaft portions 31-5a and 31-4a are fitted into the bearing holes 25-5-2 and 25-6-2. Let Here, since the first link 31 and the second link 32 are both vertical, the gear portion 31-7a does not mesh with the gear portion 31-6, and the first link 31 and the second link 32 are assembled. Is performed without interfering with the gear portions 31-6 and 31-7a.

  About step 72.

  Next, as shown in FIG. 9B, the first link 31 is rotated in the CC direction and the second link 32 is rotated in the C direction, so that the gear portion 31-6 and the gear portion 31-7a are moved. Engage. As shown in FIG. 9C, the first link 31 and the second link 32 are rotated to the final position where the opening angle is approximately 180 degrees.

  About step 73.

  Finally, as shown in FIG. 9C, the key top 51 is covered and pressed strongly. As a result, the sliding shaft portion 31-3 is temporarily bent and spring-backed as indicated by the alternate long and short dash line in FIG. 7 (B), and the tips of the arm portions 21-3b and 21-4b and the stopper portion. Relatively enters between 21-7 and fits into the sliding guide path 21-3c. When inserted, due to the relationship d> e, the sliding shaft 31-3 is not easily pulled out of the sliding guide path 21-3c. Similarly, in the sliding shaft 31-3a, the sliding shaft 31-3a snaps between the tip of the arm 21-5b, 21-6b and the stopper 21-8, and the sliding guide path 21-5c. Fit in.

  As can be seen from the above, the key switch 20 can be easily assembled without using an assembly jig and tool.

  FIG. 10 shows a key switch 20A according to the second embodiment of the present invention. FIG. 4A shows a state before the operation, and FIG. 4B shows a state when the push-down operation is performed.

  In the key switch 20A, a bearing hole is provided in the key top 51A, a sliding guide portion is provided in the housing 25A, and the first link 31 and the second link 32 are formed in an inverted V shape.

  When the key top 21A is pressed, for example, first, the first link 31 is rotated in the CC direction, and this rotation is caused by the second link via the sector gear portions 31-6 and 31-7a. 32, the second link 31 is rotated in the C direction at the same speed as the first link 31, and is opened until the opening angle is about 180 degrees as shown in FIG. And is accommodated in the flat space 21-1a of the key top 21A. Similarly to the above case, the key top 21 is supported by the first and second links 31 and 32, and descends in the Z1 direction while maintaining a horizontal posture without being inclined at all.

  The key switch 20A has the same effect as that of the key switch 20, and in addition, the meshing fan-shaped gear portions 31-6 and 31-7a are arranged on the back side of the key top 21A. Therefore, it has an effect that it is difficult to enter the sector gear portions 31-6 and 31-7a in which dust is meshed and is resistant to dust.

  The housings 25 and 25A may be of a size that allows a plurality of key switches to be arranged.

  FIG. 11 shows a key switch 20B according to a third embodiment of the present invention. FIG. 4A shows a state before the operation, and FIG. 4B shows a state when the push-down operation is performed. The key switch 20B is configured to be easily assembled by improving the key switch 20A of the second embodiment.

  As shown in an exploded view in FIG. 12, the key switch 20B includes a key top 21B, a housing 25B, and a link mechanism 27B.

  As shown in FIGS. 13 and 14, the key top 21B has first to fourth bearing portions 21B-11 to 21B-14.

  The first and second bearing portions 21B-11 and 21B-12 include two inverted U-shaped recesses 21B-15 and 21B-16 on the rib 21B-10 on the lower surface of the key top body 21-1. One slit 21B-17 is formed between the two inverted U-shaped recesses 21B-15 and 21B-16.

  As shown in FIG. 14, the first bearing portion 21B-11 has a finger portion 21B-18, a finger portion 21B-19, and an inverted U-shape between the finger portion 21B-18 and the finger portion 21B-19. Of the concave portion 21B-15. The inverted U-shaped recess 21B-15 includes a circular portion 21B-15a having a diameter D1, a tapered inlet portion 21B-15b having a minimum width W1 shorter than the diameter D1, and a small depth at the back of the circular portion 21B-15a. It consists of a small recess 21B-15c. The diameter D1 is slightly smaller than the diameter D10 of the rotation shaft portion 31-4 of the first link 31B described later. The finger part 21B-18 can be elastically bent in the X1 direction, and the finger part 21B-19 can be elastically bent in the X2 direction, that is, in the direction in which the inlet part 21B-15b expands. The second bearing portion 21B-12 has the same structure as the first bearing portion 21B-11. The third and fourth bearing portions 21B-13 and 21B-14 also have the same structure as the first bearing portion 21B-11.

  The link mechanism 27B has a structure in which a first link 31B and a second link 32B, both of which are substantially U-shaped, are combined in a substantially inverted V-shape.

  As shown in FIGS. 15A and 15B, the first link 31B is shown in FIG. 7 except that it has protruding sliding shaft portions 31B-3a and 31B-3b as semi-cylindrical portions. The first link 31 has the same shape. In the protruding sliding shaft portion 31B-3a, a portion on the sector gear portion 31-6 side from the center line 70 of the first arm portion 31-1 is removed from the cylindrical shape having a diameter D2, and the sector gear portion 31-6 is removed. It has a semi-cylindrical shape in which a portion on the opposite side to the side is left, and has a semicircular circumferential surface 31B-3a-1. The width W2 of the protruding sliding shaft portion 31B-3a in the direction perpendicular to the center line 70 is ½ of D2. The protruding sliding shaft portion 31B-3b on the opposite side has the same shape as the protruding sliding shaft portion 31B-3a. The second link 32B is the same component as the first link 31B, and is simply changed in direction.

  As shown in FIGS. 12 and 16, the housing 25 </ b> B has first to fourth sliding guide portions 25 </ b> B- 11 to 25 </ b> B- 14.

  The first sliding guide portion 25B-11 includes a column portion 25B-15 protruding from the upper surface of the housing main body portion 25-1, and an arm portion 25B-16 extending in the X1 direction from the column portion 25B-15. And a column part 25B-17 that protrudes from the upper surface of the housing body 25-1 and faces the tip of the arm part 25B-16. A sliding guide path 25B-18 extends in the X1 and X2 directions between the column portions 25B-15 and 25B-17, the arm portion 25B-16, and the housing body 25-1. is there. There is an inlet 25B-19 at the end of the sliding guide path 25B-18 in the X1 direction, that is, between the tip of the arm 21B-16 and the column 21B-17. The sliding guide path 25B-18 has a width W3 equal to the diameter D2. The width W4 of the inlet portion 25B-19 is slightly larger than the width W2 and smaller than the diameter D2. The second to fourth sliding guide portions 25B-12 to 25B-14 have the same configuration as the first sliding guide portion 25B-11.

  Next, assembly of the key switch 20B shown in FIGS. 11 and 12 will be described with reference to FIGS. 17, 18, 19, and 20. FIG.

  As shown in FIG. 17, the upper part of the key switch 20B includes (1) a step 70B for incorporating the first link 31B into the housing 25B, and (2) incorporating the second link 32B into the housing 25B. Assembling is performed in the order of step 71B for combining with 31B, (3) step 72B for tilting the first link 31B and second link 32B in the closing direction, and (4) step 73B for assembling the key top 21B to the link mechanism 27B.

  About Step 70B.

First, as shown in FIG. 18A, a first link 31B and a second link 32B (which are the same parts as the first link 31B) are prepared, and the first link 31B is projected first. The sliding shaft portion 31B-3a is held in a vertical posture facing downward, and is moved downward toward the inlet portion 25B-18 as it is. Accordingly, as shown in FIG. 19A, the protruding sliding shaft portion 31B-3a passes through the inlet portion 25B-18 and enters the sliding guide path 25B-18. Similarly, the protruding sliding shaft portion 31B-3b on the opposite side is fitted into the third sliding guide portion 25B-13. In addition, the sliding shaft portion 31B-3 is in contact with the upper surface of the housing main body portion 25-1.

  Next, the second link 32B is lowered in the vertical posture as in the case of the first link 31B, and the projecting slide shaft portions 31B-3b and 31B-3a are moved to the second and fourth slides, respectively. The guide portions 25B-12 and 25B-14 are fitted.

  About step 72B.

  Next, as shown in FIG. 18 (B), the first link 31B is rotated in the C direction and the second link 32B is rotated in the CC direction, that is, in the closing direction, as shown in FIG. 18 (C). Defeat to the final state. In the final state, the first link 31B and the second link 32B are substantially straight.

  The first link 31B rotates around a sliding shaft portion 31B-3 that is in contact with the housing body portion 25-1. As shown in FIG. 19B, the protruding sliding shaft portion 31B-3a does not collide with the arm portion 25B-16 and rotates at a position just below the inlet portion 25B-19 in the sliding guide path 25B-18. Move.

  When the first link 31B is slightly rotated in the C direction from the vertical posture, the protruding slide shaft portion 31B-3a enters the lower side of the arm portion 25B-16 as shown in FIG. The first link 31B is prevented from coming out of the first and third sliding guide portions 25B-11 and 25B-13.

  Moreover, when it falls to the final state, the gear part 31-6 of the 1st link 31B and the 2nd link 32B gear part 31-7 mesh.

  About Step 73B.

  Finally, as shown in FIGS. 18C and 18D, the key top 51B is covered and pressed strongly.

  First, the key top 51B is covered, and as shown in FIG. 20A, the tapered inlet portion 21B-15b of the first bearing portion 21B-11 is engaged with the rotating shaft portion 31-4 of the first link 31B. The tapered inlet portion of the second bearing portion 21B-12 is engaged with the rotating shaft portion 31-5 of the second link 32B.

  Next, the key top 51B is strongly pressed in the Z2 direction. Accordingly, as shown by a two-dot chain line in FIG. 20A, the finger portion 21B-18 is elastic in the X1 direction, the finger portion 21B-19 is elastic in the X2 direction, that is, the direction in which the entrance portion 21B-15b is expanded. As shown in FIG. 20B, the rotation shaft portion 31-4 of the first link 31B relatively passes through the inlet portion 21B-15b and enters the circular portion 21B-15a. Get in. When the rotation shaft portion 31-4 enters the circular portion 21B-15a, the finger portions 21B-18 and 21B-19 are elastically restored, and the entrance portion 21B-15b is narrowed. The rotating shaft portion 31-4 is restricted from coming out of the first bearing portion 21B-11 by the narrow inlet portion 21B-15b. Further, the finger portions 21B-18 and 21B-19, which have been restored substantially elastically, have a rotating shaft portion with a small force F10 that does not obstruct the rotation of the rotating shaft portion 31-4 at all by the elastic force remaining in itself. It is pressing on the peripheral surface of 31-4. Therefore, the rotating shaft portion 31-4 is supported by the first bearing portion 21B-11 without any backlash.

  As can be seen from the above, the key switch 20B can be easily assembled without using an assembly jig and tool. Further, since the first link 31B and the second link 32B do not require the operation of squeezing the tips of the pair of first arm portions 31-1 and 31-2, the key switch 20 of the first embodiment is used. This is simpler than the work of incorporating the first link 31 and the second link 32B.

  Here, the operation of fitting the rotation shaft portion 31-4 to the first bearing portion 21B-11 will be described. Since both the finger portions 21B-18 and the finger portions 21B-19 are bent, the entrance portion is easily and smoothly expanded as compared with the case where only one finger portion is bent, and the above-described operation is performed smoothly.

  Next, the operation of the key switch 20B will be described.

  Before the operation, the key switch 20B is in the state shown in FIG. The key top 21B is pushed up by a rubber actuator 26, and the first link 31B and the second link 32B have an inverted V shape.

  When the key top 21B is pressed, first, the first link 31B is rotated in the CC direction, and this rotation is transmitted to the second link 32B via the sector gear portions 31-6 and 31-7a. The second link 32B rotates in the C direction at the same speed as the first link 31B, and the protruding slide shaft portion 31B-3a of the first link 31B is guided by the first slide guide portion 25B-11. Then, the protruding slide shaft portion 31B-3b of the second link 32B is guided by the second slide guide portion 25B-12 and slides in the X2 direction. That is, the first link 31B and the second link 32B are rotated in a direction in which the opening angle increases symmetrically, and as shown in FIG. 11B, the opening angle is about 180 degrees. It becomes substantially straight and is accommodated in the flat space of the key top 21B.

  Here, the four rotation shaft portions 31-4 and 31-5 of the first link 31B and the second link 32B and the first to fourth bearing portions 21B-11 to 21B-14 are free from backlash. Therefore, when the key top 21B is touched to press the key top 21B, the key top 21B does not wobble. Good operational feeling can be obtained as long as there is no wobble. Therefore, the key switch 20B has high operation quality.

  Similarly to the above case, the key top 21B is supported by the first and second links 31B and 32B, and descends in the Z1 direction while maintaining a horizontal posture without any inclination.

  When the fingertip is released from the key top 21B, the key top 21B is pushed up in the Z1 direction by the elastic force of the rubber actuator 26. The first and second links 31B and 32B rotate so as to stand up contrary to the above, and the key top 21B is supported by the first and second links 31B and 32B and is lifted while maintaining a horizontal posture. To do.

  When the key top 21B is pushed down to the maximum, as shown in FIG. 11 (B), the protruding sliding shaft portion 31B-3a slides maximum in the X1 direction and reaches directly below the inlet portion 25B-19. The sliding shaft portion 31B-4a slides to the maximum in the X2 direction and reaches directly below the inlet portion. Here, the first and second links 31B and 32B lie sideways, and the protruding sliding shaft portion 31B-3a has its circumferential surface 31B-3a-1 facing the inlet portion 25B-19 side, The protruding sliding shaft portion 31B-3a does not come out of the inlet portion 25B-19. Similarly, the protruding sliding shaft portion 31B-4a does not come out of the inlet portion. Therefore, the link mechanism 27B does not come off from the housing 25B, and the key switch 20B has high reliability.

  In addition, as shown in FIG. 21, the bearing portion has a structure having two inverted U-shaped concave portions 21B-15 and 21B-16 on the rib 21B-10 on the lower surface of the key top body 21-1, that is, the above-described configuration. The structure which does not have this slit 21B-17 may be sufficient.

  The housings 25, 25A, and 25B may be of a size that allows a plurality of key switches to be arranged.

  Next, a modification of the second and third embodiments will be described as a fourth embodiment. In the second (third) embodiment, the first link 31 (31B) and the second link 32 (32B) constituting the link mechanism are rotatably supported by the key top 21A (21B), respectively. Yes. In other words, the first link 31 (31B) and the second link 32 (32B) of the second (third) embodiment are slidably supported by the housing 25, respectively. The fourth embodiment described below is characterized by providing means for preventing problems that may occur in the second and third embodiments.

  FIG. 22 is a diagram illustrating the arm portion 31-1 of the first link used in the fourth embodiment. The same parts as those described above are denoted by the same reference numerals. FIG. 22A is a front view, and FIG. 22B is a left side view. As shown in FIG. 22, a built-up portion 31-9 is provided on the side opposite to the gear portion 31-6. The edge 31-10 of the built-up portion 31-9 is formed to have a predetermined curve. Such a built-up portion is provided on each of the two arm portions 31-1 and 31-2 of the first link 31B and the second link 32B shown in FIG.

  FIG. 23 is a perspective view showing a housing used in the fourth embodiment, and FIG. 24 is a plan view of the key switch of the fourth embodiment, showing a state where the key top is seen through. A main body 25C-1 of a housing 25C shown in FIG. 23 has a recess 25C-2 therein, and four sliding guide portions 25C-11, 25C-12, 25C-13, and 25C having a substantially L-shaped cross section therein. -14. A protrusion 25C-7 having a circular opening 25C-8 is provided at the center of the recess. Although not shown, a rubber actuator 16 as shown in FIG. 11 is provided around the protrusion 25C-7, and when the key top 21B is pressed, the protrusion of the actuator 16 becomes a circular opening 25C-8. Then, the contact is driven (membrane sheets 22a and 22b shown in FIG. 25 described later come into contact with each other). Further, in the concave portion 25C-2, along the sliding guide portions 25C-11, 25C-12, 25C-13, and 25C-14, the flat rail portions 25C-3, 25C-4, and 25C are provided inside these portions. -5 and 25C-6 are provided. A sliding shaft portion (corresponding to 31-3 in FIG. 12) can slide on the rail portions 25C-3, 25C-4, 25C-5, and 25C-6. The rail portions 25C-3 and 25C-4 may be configured as one continuous rail, and 25C-5 and 25C-6 may be configured as one continuous rail.

  In FIG. 23, the rotation shaft portions 31-4 and 31-5 of the first and second links 31B and 32B rotate to the key top 21A (21B) as in the second or third embodiment. Supported as possible.

  FIGS. 25A to 25G are diagrams illustrating the operation of the arm portion 31-1 of the first (or second) link. In the state where the chamfered edge portion (stopper portion) 25C-1b of the housing is in contact with the edge portion 25-10 of the built-up portion 31-9, the protruding slide shaft portion 31B-3a (shown in FIG. 12: FIG. 22). Then, it is provided on the opposite side of the built-up portion 31-9) slides in the sliding guide portion 25C-12, and the sliding shaft portion 31-3 slides on the rail portion 25C-4. Thus, since the build-up part 31-9 moves while rubbing the edge part 25-10, it is possible to prevent backlash on the left and right in FIG. Moreover, since the build-up part 31-9 is located between the arm part 31-1 and the sliding guide part 25C-12, the clearance between this shown in FIG. 24 can be set small. Further, since the sliding shaft portion 31-3 slides on the rail portion 25C-4, as compared with the case where the sliding shaft portion 31-3 slides on the entire surface of the housing 25B as shown in FIG. Therefore, the occurrence of catches when garbage enters is reduced.

  FIG. 26 shows a keyboard 60 having a configuration in which a plurality of key switches 20, 20A, or 20B according to the first to fourth embodiments are provided side by side. This keyboard 60 is a thinner and thinner profile than the conventional one, and is applied to a notebook personal computer.

It is a disassembled perspective view of 1st Example of the key switch of this invention. FIG. 2 is a plan view showing the key switch of FIG. 1 through a key top. FIG. 3 is a sectional view taken along line III-III in FIG. 2. FIG. 4 is a cross-sectional arrow view taken along line IV-IV in FIG. 2. FIG. 5 is a sectional view taken along line V-V in FIG. 2. It is a figure shown in the state where the key top was turned upside down. It is a figure which shows a 1st link. It is an assembly process figure of a key switch. It is a figure explaining the assembly of the key switch of FIG. It is a figure which shows 2nd Example of the key switch of this invention. It is a figure which shows 3rd Example of the key switch of this invention. It is a disassembled perspective view of the key switch of FIG. It is a figure shown in the state where the key top was turned upside down. It is a figure which expands and shows a bearing part. It is a figure which shows a 1st link. It is a figure which shows a housing. It is an assembly process figure of a key switch. It is a figure explaining the assembly of the key switch of FIG. It is a figure explaining incorporation of the 1st link. It is a figure explaining fitting with a bearing part and a rotating shaft part. It is a figure which shows the modification of a bearing part. It is a figure which shows the arm part of the link of the link mechanism used in the 4th Example of this invention. It is a perspective view of the housing used in the 4th example. It is a top view which shows the key switch of 4th Example seeing through a key top. It is a figure for demonstrating operation | movement of the link used in the 4th Example. It is a figure which shows the keyboard provided with the key switch by the 1st thru | or 4th Example. It is a figure which shows an example of the key switch of a prior art example.

Explanation of symbols

20, 20A, 20B Key switch 21, 21A, 212B Key top 21-1 Key top body 21-1a Flat space 21-1b, 21-1c Recessed portion 21-2 Circular convex portion 21-3 to 21-6 Sliding guide Part 21-3a to 21-6a Column part 21-3b to 21-6b Arm part 21-7, 21-8 Stopper part 21B-10 Rib 21B-11 to 21-B14 First to fourth bearing parts 21B-15 , 21B-16 Reverse U-shaped recess 21B-15a Circular portion 21B-15b Tapered inlet portion 21B-15c Small recess 21B-17 Slit 21B-18, 21B-19 Finger portion 22 Membrane switch 23 Membrane sheet 24 Support panel 25 Housing 25-1 Housing body 25-2 Circular opening 25-3, 25-4 Elongated opening 25-5 25-6 ribs 25-5-1, 25-5-2, 25-6-1, 25-6-2 bearing holes 25B-11 to 25B-14 first to fourth sliding guide portions 25B-15, 25B-17 Pillar part 25B-16 Arm part 25B-18 Sliding guideway 25B-19 Entrance part 26 Rubber actuator 27 Link mechanism 31, 31B First link 31-1, 31-2 Arm part 31-3 Sliding Dynamic shaft portion 31B-3a, 31B-3b Protruding sliding shaft portion 31B-3a-1 Half-circumferential circumferential surface 31-4, 31-5 Rotating shaft portion 31-6, 31-7 Gear portion 32, 31B Second Link 40, 41, 42, 50, 51, 52 Teeth 43, 44, 53, 54 Tooth groove 59 Space 60 Keyboard

Claims (2)

A key top that is pushed down,
A housing disposed below the key top;
An actuator which is located below the key top and is pressed and elastically deformed when the key top is pushed down to close a contact point and apply a pushing force to the key top;
The key comprises a first link and a second link provided between the housing and the key top, and the key top that has been pushed down is lowered, and the key top is raised by an elastic restoring actuator. In a key switch having a link mechanism for supporting a top with respect to the housing,
The key top is configured to have a bearing portion on the lower surface thereof,
The housing is configured to have, on the upper surface thereof, a sliding guide portion that slides and guides in a direction perpendicular to a direction in which the key top is pushed down.
Each of the first and second links has a sliding shaft portion at one end of the arm portion, and a rotation transmission means portion and a rotation shaft portion at the other end of the arm portion,
In the link mechanism, the first link and the second link are slidably fitted to the slide guide portion and supported by the housing, and the rotation transmission means portion. And the pivot shaft portion is pivotably engaged with the bearing portion of the key top, and the arm portion of the first link and the second link are engaged with each other. A key switch characterized in that the arms are arranged in an inverted V shape without crossing the arms. A keyboard characterized in that the key switch according to claim 1 is arranged.

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