JP3817544B2 - Key switch device - Google Patents

Description

  The present invention relates to a key switch device, and more particularly to a key switch device suitable for use in a thin keyboard attached to a notebook word processor, a notebook personal computer, or the like.

  Conventionally, as a key switch device used for this kind of keyboard, a key top having a key stem is inserted and guided through a holder portion formed on a holder plate, and a switching member is disposed below the key stem. The key switch device is generally used. Such a key switch device slides and guides the vertical movement of the key stem through the holder part, and presses the switching member by the lower part of the key stem to perform the switching operation.

  Further, as a key switch device using a large key top such as a space key or a return key, in order to prevent the key top from being depressed in a tilted state when the key top is depressed, JP-A-60- There are known key switch devices described in Japanese Patent No. 62017, Japanese Patent Application Laid-Open No. 64-7441 and US Pat. No. 4,433,225.

  The key switch device described in Japanese Patent Application Laid-Open No. 60-62017 supports a key top on two scissors-like members that are crossed like scissors by a shaft and switches to a position away from the center of the key top. The member is arranged. When the key top is pressed, a plurality of pins formed at the ends of the scissors-like members are slid and guided in the horizontal direction, and the key stem disposed on the back surface of the key top is moved up and down via the holder portion. The switching member is pressed by the key stem while sliding and guiding.

  The key switch device described in Japanese Patent Application Laid-Open No. 64-7441 has the same basic configuration as the key switch device described in Japanese Patent Application Laid-Open No. 60-62017. It is characterized in that it can be easily attached and detached.

  U.S. Pat. No. 4,433,225 discloses a key switch device having an L-shaped key top. This key switch device has a scissors-like member in which the central portion of the arm is coupled by a shaft. The scissor-like member has four first, second, third, and fourth ends, and the first and second ends are in the horizontal direction within the traveled portion of the L-type key top. It is slidable. However, since the key switch portion is located at a different location from the scissors-like member, it cannot be used as a key switch device by itself, and a key stem and many other parts are required, resulting in a complicated structure.

  The key switch device described in each of these publications guides the vertical movement of a large key, such as a space key, while maintaining the horizontal state of the key top no matter which part of the key top is pressed. It can be done. Thus, the key switch devices described above are common in that the key stem for pressing the switching member is slid up and down through the holder portion and the switching member is pressed by the key stem. Yes.

On the other hand, Japanese Utility Model Laid-Open No. 2-5236 describes a key switch device that does not include a key stem and a holder portion that are slidably guided in a vertical direction. This key switch device includes two rectangular frames, and the two frames are crossed in an X shape to serve as a key top support member. A protrusion that protrudes downward is provided at the center of the lower surface of the key top, and the protrusion is configured to press a rubber spring that is a switching member. In this key switch device as well, as with the key switch device described above, no matter which part of the key top is pressed, the key top can be lowered while being held horizontally without tilting the key top.
JP-A-60-62017 Japanese Patent Application Laid-Open No. 64-7441 US Pat. No. 4,433,225 Japanese Utility Model Publication No. 2-5236

  However, in recent years, along with the downsizing and thinning of word processors and personal computers, keyboards attached thereto have been directed to downsizing and thinning. On the other hand, a large stroke is required to improve the operability of key input and ensure the certainty of key input. Under such circumstances, there has been a problem that the key switch device generally used cannot obtain a sufficient key stroke.

In such a commonly used key switch device, if it is attempted to reduce the thickness of the keyboard, the portion of the key stem that is slid and guided by the holder portion is reduced, and the key stem and Twisting occurs between the holder and the holder.
Conversely, to prevent this, there is a dilemma that if the part where the key stem is slid and guided by the holder part is enlarged, the key stroke is reduced.

  Here, if a twist occurs between the key stem and the holder portion when the key top is pressed, this causes a sliding noise, which significantly impairs the operability of the key. Further, the twisting generated between the key stem and the holder portion is unlikely to occur because the key stem is pressed vertically when the center portion of the key top is always pressed.

  Therefore, in order to prevent the occurrence of such twisting, it is conceivable that the key operation area is reduced so that the center of the key top is always pressed. In this case, however, the key operability is significantly impaired. There is no difference from the above.

  In addition, the key switch device described in each of the above publications is not particularly directed to reducing the thickness of the keyboard. Therefore, it is necessary to provide a pressing member for pressing the switching member so as to protrude downward from the key top, which makes it difficult to reduce the thickness. Further, since the pressing member needs to be formed on the back surface of the key top, the structure of the key switch device is complicated, resulting in an increase in cost and difficulty in assembly.

  The present invention has been made in order to solve the above-described problems, and does not require a key stem structure, can maintain a large key stroke while supporting a thin keyboard, and has a simple structure for key input. It is an object of the present invention to provide a key switch device that has good operability and enables reliable key input.

To achieve this object, a key switch device according to a first aspect of the present invention includes a key top, a holder member disposed at a position below the key top and having a through hole, a first link member, and a second link. A guide support member for guiding and supporting the vertical movement of the key top by connecting the key top and the holder member, and a lower part of the holder member. A circuit board disposed at the top, a rubber spring that urges the key top upward and performs a switching operation as the key top moves up and down, and a first locking pin formed at the lower end of the first link member, A second locking pin formed at the lower end of the second link member; a sliding locking portion formed integrally with the holder member, arranged around the through hole, and slidably locking the first locking pin; ,holder In the key switch device, which is integrally formed with the material and is arranged around the through hole, and includes a rotation locking portion that rotatably locks the second locking pin, the rubber spring is the through hole of the holder member. And the upper part of the rubber spring protrudes upward from the upper surface of the sliding engagement part and the rotation engagement part of the holder member through the through hole. When pressed, the upper portion of the rubber spring is pressed through the guide support member, the rubber spring is deformed accordingly, and the first locking pin is slid on the circuit board in the sliding locking portion, and The second locking pin is rotated by the rotation locking portion.

  According to the key switch device of the present invention having the above-described configuration, the key top is urged upward by the rubber spring when the key top is not pressed. When the key top is pressed from this state, the key top is guided downward by the first link member and the second link member arranged in an X shape in a side view against the biasing force of the rubber spring, Switching operation is performed.

  On the other hand, when the pressing of the key top is released, the key top is urged upward by the urging force of the rubber spring, and the key top is pushed upward while being supported by the first link member and the second link member. Return to the position.

According to the key switch device of the present invention, since the rubber spring is placed on the circuit board in the through hole of the holder member, the thickness of the holder member can be effectively used to increase the height of the entire key switch device. The key switch device can be made thinner as compared with the case where the rubber spring is placed on the upper surface of the holder member.
Further, by placing a circuit board below the holder member in which the through hole is formed and placing a rubber spring on the circuit board, the upper portion of the rubber spring is integrally formed with the holder member through the through hole. Since it protrudes above the upper surfaces of the sliding engagement portion and the rotation engagement portion, the upper portion of the rubber spring is reliably pressed, and the rubber spring can be deformed accordingly. Therefore, even when the circuit board is disposed below the holder member, the urging force of the rubber spring placed on the circuit board can be transmitted to the key top to urge the key top upward.
Further, the vertical movement of the key top is guided through both link members arranged in an X shape when viewed from the side, and the first locking pin is slid on the circuit board within the sliding locking portion. Since the stop pin is rotated by the rotation locking portion, the switching operation is performed, so that the key switch configuration is unnecessary, and the key switch device is thinned while maintaining the size of the key stroke. be able to.

  DETAILED DESCRIPTION Hereinafter, embodiments of the present invention will be described in detail with reference to the drawings. 1 to 3 show a first embodiment of the present invention. FIG. 1 is a side sectional view of a key switch device. In FIG. 1, a key top 1 is molded from a synthetic resin such as ABS resin, and letters such as alphabets are formed on its upper surface by printing or the like. Moreover, from the back surface of the key top 1, the rotation latching | locking part 2 and the sliding latching | locking part 3 are integrally provided with the keytop 1 main body toward the downward direction.

The rotation locking portion 2 is a lock that rotatably locks third locking pins 13 and 14 formed at one end of one of the two link members 7 and 8 described later. A hole 4 is formed, and the fourth locking pins 23 and 24 formed at one end of the other link member 8 are slidably locked to the sliding locking portion 3 in the horizontal direction. A locking groove 5 is formed.

  A guide support member 6 that guides and supports the vertical movement of the key top 1 is disposed below the key top 1. The guide support member 6 includes two link members 7 and 8.

  As shown in FIG. 2, one link member 7 is formed by integrally forming two base end portions 10 and 11 at both ends of the base portion 9. A shaft 12 extends from one side surface of the central portion of the base 9, and the shaft 12 is supported by a shaft hole 20 formed in the other link member 8 described later.

As shown in FIG. 1, the third locking pins 13 and 14 and the first locking pins 15 and 16 of the link member 7 are aligned on a straight line with the shaft 12 as the center, and the distance from the shaft 12 is equal. Configured as follows. Further, the second locking pins 21 and 22 and the fourth locking pins 23 and 24 of the link member 8 are arranged in a straight line with the shaft hole 20 as the center, and are configured to have the same distance from the shaft hole 20. .

  The two link members 7 and 8 are bent so as to protrude upward at the positions of the lower base end portions 11 and 18 in a state where the shaft 12 and the shaft hole 20 are rotatably connected. Therefore, as shown in FIG. 1, since it is configured to have a large space on the lower side of the shaft support portion A, a rubber spring 31 having a substantially trapezoidal shape in side view, which will be described later, can be efficiently stored below the shaft support portion A. is there.

  Further, as shown in FIG. 1, both link members 7, 8 have a reduced thickness at the distal end portions of the upper base end portions 10, 19. Therefore, even when the key top 1 is pressed, the upper base end portions 10 and 19 and the lower base end portions 11 and 18 of the link members 7 and 8 can come into contact with each other in the middle of pressing the key top 1. Absent. Therefore, the key top 1 is configured so as to be able to secure a sufficient key stroke without obstructing the pressing operation halfway.

The link member 7 as shown in FIG. 2, from the side of both end distal portion 10A of the upper base end portion 10, the third lock pin 13, 14 are extended, the third engaging pin 13 , 14 are rotatably engaged with the engaging holes 4 formed in the rotational engaging portion 2 of the key top 1 described above. Further, the lower base end portion 11 is formed in a U shape in a plan view, and first locking pins 15 and 16 similar to the above are extended from the side surface of the U-shaped extension portion 11A. . The first locking pins 15 and 16 are slidably locked to a sliding locking portion 26 formed on a holder member 25 described later.

  Further, as shown in FIG. 3, the link member 8 is formed by integrally forming two upper and lower base end portions 18 and 19 at both ends of the base portion 17. A shaft hole 20 is formed in the central portion of the base portion 17, and the shaft 12 provided in the base portion 9 of the link member 7 is inserted into the shaft hole 20 as described above.

The lower base end portion 18 is formed in a U shape in plan view, and second locking pins 21 and 22 are extended from the U-shaped both ends extending portion 18A. The second locking pins 21 and 22 are rotatably locked to a rotation locking portion 27 formed on a holder member 25 described later.

The fourth lock pin 23, 24 from both extending portions 19A similar to the above base end portion 19 and is extended, according the fourth lock pin 23, 24 slide in the key top 1 described above It is slidably locked in a locking groove 5 formed in the locking portion 3.

  As described above, the guide support member 6 is configured by inserting the shaft 12 formed in the base portion 9 of one link member 7 into the shaft hole 20 formed in the base portion 17 of the other link member 8. Both the link members 7 and 8 can be rotated with respect to each other via a shaft support portion A composed of the shaft 12 and the shaft hole 20.

Next, a holder member 25 is disposed below the guide support member 6, and on the holder member 25, a first locking pin 15 extended to the lower base end portion 11 of the link member 7, 16 and a sliding locking portion 26 and a rotation locking portion 27 for locking the second locking pins 21 and 22 extended to the lower base end portion 18 of the link member 8, respectively. Yes.

The sliding locking portion 26 is integrally formed in a convex shape from the holder member 25 and is provided with a long locking groove 28. The locking groove 28 has a first locking of the link member 7. The pins 15 and 16 are locked so as to be slidable in the horizontal direction. Similarly to the sliding locking portion 26, the rotation locking portion 27 is integrally formed in a convex shape from the holder member 25 and is provided with a locking hole 29. The locking hole 29 is provided with the link. The second locking pins 21 and 22 of the member 8 are rotatably locked.

In the above configuration, the rotation formed on the rotation locking portion 2 and the holder member 25 formed on the back surface of the key top 1 existing on the left side in FIG. 1 with reference to the perpendicular L passing through the center of the shaft support portion A. The locking portion 27 is provided with a locking hole 4 and a locking hole 29 for locking the third locking pins 13 and 14 and the second locking pins 21 and 22 to be rotatable. .

Further, the sliding engagement portion 3 formed on the back surface of the key top 1 existing on the right side of the perpendicular L in FIG. 1 and the sliding engagement portion 26 formed on the holder member 25 are respectively connected to the fourth engagement. The locking grooves 5 and the locking grooves 28 for locking the locking pins 23 and 24 and the first locking pins 15 and 16 so as to be slidable in the horizontal direction are provided.

  A flexible circuit board 30 on which a predetermined circuit pattern (not shown) including a switch electrode is formed is disposed below the holder member 25, and a reverse cup-shaped rubber is provided as a switching member at a position corresponding to the switch electrode. A spring 31 is placed. The rubber spring 31 has a known movable electrode inside, and a shaft support portion A that supports the two link members 7 and 8 so as to be rotatable with respect to each other is opposed to the central portion of the upper surface thereof. Be placed.

  As a result, when the shaft support portion A moves downward as the key top 1 is pressed, the shaft support portion A presses the rubber spring 31, and when the pressing amount exceeds a certain limit, the rubber spring 31 is bent and the rubber is pressed. The switch electrode is short-circuited by the movable electrode in the spring 31.

  Further, a switch support plate 32 is disposed below the flexible circuit board 30, and the switch support plate 32 supports the guide support member 6 that supports the flexible circuit boards 30, the rubber springs 31, and the key tops 1. To do.

Next, the operation of the key switch device having the above embodiment will be described.
When the key top 1 is pressed downward, the third locking pins 13 and 14 of the link member 7 are counterclockwise in the locking hole 4 of the rotation locking portion 2 as the key top 1 moves downward. And the fourth locking pins 23 and 24 of the link member 8 slide in the horizontal direction (the right direction in FIG. 1) in the locking groove 5 of the sliding locking portion 3.

At the same time, the second locking pins 21 and 22 of the link member 8 rotate clockwise in the locking holes 29 of the rotation locking portion 27 of the holder member 25 and the first locking of the link member 7. The pins 15 and 16 slide in the horizontal direction (right direction in FIG. 1) in the locking groove 28 of the sliding locking portion 26.

  As a result, the shaft support portion A that pivotally supports the link members 7 and 8 moves downward and gradually presses the rubber spring 31. When the pressing amount exceeds a certain limit, the rubber spring 31 is Cramped. Thereby, the movable electrode in the rubber spring 31 short-circuits the switch electrode on the flexible circuit board 30, and a predetermined switching operation is performed.

When the pressing of the key top 1 is released, the shaft support portions A of the link members 7 and 8 are pushed upward by the elastic restoring force of the rubber spring 31. Accordingly, the third locking pins 13 and 14, the second locking pins 21 and 22, the first locking pins 15 and 16, and the fourth locking pins 23 and 24 are the reverse of the operation described above. As a result, the key top 1 is returned to the original position.

Here, the third locking pins 13 and 14 and the second locking pins 21 and 22 do not move in the horizontal direction but only rotate within the locking holes 4 and 29, respectively. Since 1 does not move in the horizontal direction, it does not collide with adjacent keys, and is moved up and down while maintaining the horizontal state of the key surface of the key top 1.

  As described above, the rubber spring 31 has a substantially trapezoidal shape when viewed from the side, and the angle of the side surface due to the length of the upper base and the length and height of the lower base is determined according to the desired key touch. Further, the height of the trapezoidal portion, that is, the height of the rubber spring is determined according to the key stroke, and a higher one is preferred. However, in view of the thickness of the entire device, it is obvious that this rubber spring cannot be made so large.

  Therefore, in this embodiment, both the link members 7 and 8 are bent as described above so that a large space can be taken under the shaft support portion A. Therefore, in this embodiment, the structure of the present invention is applied to the device described in Japanese Patent Application Laid-Open No. 60-62017 or Japanese Patent Application Laid-Open No. 64-7441 in which both link members are substantially straight when viewed from the side. Compared to the above, a thinner and larger keystroke can be obtained.

  Further, as described above, since the thickness of the distal end side of the upper base end portions 10 and 19 of both link members 7 and 8 is reduced in a side view, a sufficient stroke can be achieved without interfering with the keystroke operation. Can be secured.

  As described in detail above, the key switch device according to the present embodiment arranges the shaft support portion A that supports the two link members 7 and 8 with respect to each other at a position corresponding to the rubber spring 31, and the shaft support portion A. The rubber spring 31 is pressed down through. Therefore, it is possible to realize a key switch device that does not require a configuration for guiding the key stem by the key holder portion as in the conventional key switch device and does not require a special configuration for pressing the rubber spring 31.

  As a result, the key stroke can be increased corresponding to the thinning of the keyboard, and therefore, the key operability is good and the key input can be surely performed, and the key top 1 having a simple structure is used to reduce the cost. A low key switch device can be provided. In particular, in the key switch device according to the present embodiment, the configuration for guiding the key stem by the key holder portion can be completely eliminated. Therefore, unlike the conventional key switch device, when the key is pressed, the key stem is interposed between the key stem and the key holder portion. There is no sliding noise, and there is no need to reduce the key operation area and press the center of the key.

Further, in the key switch device according to the present embodiment, the third locking pins 13, 14 locked in the locking holes 4 of the rotation locking portion 2 and the locking holes 29 of the rotation locking portion 27, Since the second locking pins 21 and 22 only rotate within the locking holes 4 and 29 without moving in the horizontal direction even when the key top 1 is pressed, the key top 1 is moved in the horizontal direction. There is nothing. Therefore, it is possible to provide a key switch device that has good key operability and can reliably perform key input without collision between adjacent keys.

  In addition, this invention is not limited to the said Example, A various deformation | transformation and improvement are possible in the range which does not deviate from the summary of this invention.

  For example, the link members 7 and 8 in this embodiment can of course obtain the same effect by using the same kind of members combined in a pantograph shape. Further, in this embodiment, the rubber spring 31 is pushed down by the shaft support portion A of the link members 7, 8. However, the rubber spring 31 is pushed down by the link members 7, 8 or another member provided on the key top 1. Of course, the same effect can be obtained.

  Next, a second embodiment of the present invention will be described with reference to FIGS. FIG. 4 is a side sectional view of the key switch. The key switch 101 includes a key top 102, a guide support member 103 in which a first link 104 and a second link 105 are arranged in scissors in a side view, and the guide support member. A cap-shaped rubber spring 106 pressed at 103, a synthetic resin holder member 107 for supporting the guide support member 103, and a switching portion 129 (see FIGS. 12 and 12) in the mounting hole 107A of the holder member 107. 13), a flexible circuit board 109 stretched on the lower surface of the holder member 107, and a reinforcing plate 110 stretched on the lower surface side thereof.

As shown in FIGS. 4 and 12, the rubber spring 106 is disposed in the mounting hole 107 </ b> A that penetrates the holder member 107 so as to cover the upper portion of the switching portion (electrical contact portion) 129 (see FIG. 13) in the flexible circuit board 109. Is inserted and arranged. The rubber spring 106 of the present invention is made of electrically insulating silicone rubber or EPDM (ethylene propylene diene methylene) or the like, and has a thick disk-like head 106A in plan view and a downward direction from the periphery of the head. The dome portion 106B having a truncated cone shape that extends and a thick-walled ridge portion 106C that extends substantially horizontally and radially outwardly on the outer periphery of the dome portion are integrally formed in a downwardly opened cap shape.
When the key top 102 is pressed, the lower surface of the head portion 106A of the rubber spring 106 pressed by the pressing portion of the first link 104 and the second link 105 abuts on the contact portion of the switching portion 129 to perform both switching. The movable contact portion 130 made of conductive rubber having conductivity for electrically turning on / off the portion is fixed. The rubber spring 106 may be formed so as to have conductivity by dispersing and filling conductive particles such as carbon black in silicone rubber.

The key top 102 formed of a synthetic resin such as ABS resin has numerals, letters, and the like on its upper surface (surface) by stamping or printing. Front and rear for locking the fourth locking pins 111A and 111B at the upper base end of the first link 104, which will be described later, on the lower surface of the key top 102 so as to be slidable in the front-rear direction of the key top 102 in a substantially horizontal direction. A hole-shaped rotation locking portion 115 for locking the longitudinal groove-shaped sliding locking portion 116 and the third locking pins 113A, 113B at the upper base end portion of the second link 105 so as to allow only rotation. And a pair of left and right engaging members 117 of the front and rear longitudinally are integrally formed or protruded by bonding with an adhesive or the like (see FIG. 6).

With reference to FIG. 7 (A), (B) and FIGS. 8-10, the 1st link 104 and the 2nd link 105 made from synthetic resins, such as glass fiber reinforced synthetic resin, are demonstrated in detail. 7A is a plan view of the first link 104, and FIG. 7B is a plan view of the second link 105.
The first link 104 is integrally formed by a base portion 118 and upper and lower base end portions 119 and 120 in a substantially H shape in plan view. Support holes 121 are drilled laterally on the side surface of the base portion 118, and second locking pins 112A and 112B are laterally disposed on the side surfaces of the arm portions 120A and 120B extending from the left and right ends of the lower base end portion 120, respectively. The fourth locking pins 111 </ b> A and 111 </ b> B are provided so as to project sideways on the side surface of the upper base end portion 119.

The second link 105 is also integrally formed by a base 122 and upper and lower base ends 123 and 124 substantially in a substantially H shape in plan view. A pivot shaft 125 is protruded laterally on one side surface of the base portion 122, and the pivot shaft 125 is rotatably fitted in the support hole 121 in the first link 104. Arm 124A extending from the right and left side ends of the lower base end portion 124 of the second link 105, the side surface of the 124B, each first locking pin 114A, projecting the 114B sideways, on a side surface of the upper base end portion 123 Has third locking pins 113A and 113B projecting sideways.

In this embodiment, in a side view (FIGS. 4, 5, 8, 9, 10, and 14), the second locking pins 112A and 112B of the first link 104, the support hole 121, and the fourth locking The pins 111A and 111B are positioned on a straight line, and the distance from the second locking pins 112A and 112B to the support hole 121 is equal to the distance from the fourth locking pins 111A and 111B to the support hole 121. Composed.
Further, the third locking pins 113A and 113B, the pivot shaft 125, and the first locking pins 114A and 114B of the second link 105 are positioned on a straight line and are pivotally supported from the third locking pins 113A and 113B. The distance from the shaft 125 is configured to be equal to the distance from the first locking pins 114A and 114B to the pivot shaft 125.

With this configuration, as will be described later, the guide support member 103 is pivotally displaced about the second locking pins 112A and 112B at the lower base end portion of the first link 104, whereby the key top 102 is held in the holder. It is possible to move up and down while maintaining a parallel state with respect to the upper surface of the member 107.

  Further, downward pressing polygonal pressing portions 131 and 132 are formed on the lower surfaces of the base portion 118 of the first link 104 and the base portion 122 of the second link 105, respectively. The upper surface of the head 106A of 106 is pressed.

  4 and 8 to 10, the pressing portion 131 in the first link 104 and the pressing portion 132 in the second link 105 are bent at an obtuse angle at the substantially central portion of the bottom surfaces of the base portions 118 and 122. It consists of two plane parts 131A and 131B and plane parts 132A and 132B that are connected. The positional relationship between the plane portions 131A and 131B and the support hole 121 and the positional relationship between the plane portions 132A and 132B and the pivot shaft 125 are the same (however, the laterally reversed relationship).

  FIGS. 12 and 13 are views showing a part of a holder member 107 made of synthetic resin such as glass fiber reinforced synthetic resin. The holder member 107 has a lower end forming part of the cap-shaped rubber spring 106. And a pair of left and right rotation locking portions 127 on the left and right edges of the mounting hole 107A. The front and rear longitudinal groove-like sliding locking portions 128 are integrally formed by injection so that the locking portions 127 and 128 are opened downward.

Here, as shown in FIG. 13, the lower part of the rotation latching part 127 and the sliding latching part 128 is open, so that a predetermined gap is formed between the predetermined upper mold and the lower mold. After the resin is injected into the holder member 107, the upper die and the lower die can be simply drawn up and down.
As a result, the pivotal locking portion 127 that pivotably locks the second locking pins 112A and 112B of the first link 104 and the first locking pins 114A and 114B of the second link 105 are provided. Forming the sliding latching portion 128 that slidably latches on the holder member 107 does not require the use of a costly slide mold, and can be formed very simply and at low cost.

Then, the second locking pins 112A and 112B at the lower base end portion of the first link 104 are inserted into the rotation locking portion 127 so as to be rotatable from the lower side, and are attached to the sliding locking portion 128. On the other hand, after the first locking pins 114A and 114B at the lower base end portion of the second link 105 are fitted and inserted so as to slide back and forth from the lower side, the flexible circuit board 109 is stretched and fixed to the lower surface of the holder member 107. To do.

At this time, since the lower portions of the rotation locking portion 127 and the sliding locking portion 128 are open, the second locking pins 112A and 112B locked to the rotation locking portion 127 and the sliding lock The first locking pins 114 </ b> A and 114 </ b> B that are locked to the locking portion 128 are rotated and slid while being placed on the upper surface of the circuit board 109.
Thereby, each 2nd locking pin 112A, 112B and 1st locking pin 114A, 114B can be locked within the thickness of the holder member 107, and aiming at the effective use for the thickness of the holder member 107 The key switch 101 can be reduced in thickness. Moreover, since each rotation latching part 127 and the sliding latching part 128 are provided with an open insertion part, the second latching pins 112A and 112B and the first latching pin are provided via each open insertion part. 114A and 114B can be easily inserted.

As shown in FIG. 11, the outer end surfaces of the fourth locking pins 111A and 111B and the first locking pins 114A and 114B of the first link 104 and the second link 105 constituting the guide support member 103 are the key tops 102 and The side surfaces (inner wall surfaces) of the sliding engagement portions 116 and 128 of the holder member 107 are in contact with each other, and thereby the movement of the key top 102 in the left-right direction in FIG. 11 during key operation is suppressed.

Further, the outer end surfaces of the third locking pins 113A and 113B and the second locking pins 112A and 112B of the first link 104 and the second link 105 are the rotation locking portions 115 and 127 of the key top 102 and the holder member 107, respectively. In other words, the movement of the key top 102 in the left-right direction (in the direction of the rotation axis) in FIG. As a result, the fourth locking pins 111A and 111B and the first locking pins 114A and 114B of the first link 104 and the second link 105 are disengaged from the sliding locking portions 116 and 128 of the key top 102 and the holder member 107. It is possible to reliably prevent the key top from being operated and to maintain the operability of the key top.

  Further, since the position of the key top 102 in the left-right direction in FIG. 11 does not move, the key top 102 does not collide with an adjacent key even when the key top 102 is pressed. In addition, since the movement of the links 104 and 105 in the left-right direction in FIG. 11 is suppressed in this way, the pivot shaft 125 is prevented from coming off from the support hole 121.

4 and 13, the sliding groove of the sliding engagement portion 128 in the holder member 107 has a front end portion 300 and a rear end portion 301, and the key top 102 is not pressed downward (free state). ), The first locking pins 114A and 114B of the second link 105 are configured to contact the front end portion 300 of the sliding groove in the sliding locking portion 128 when the key top 102 is at the highest position. Yes.

Further, as shown in FIG. 5, even when the key top 102 presses the rubber spring 106 to the maximum extent via the guide support member 103 from the highest position, the first locking pin 114 </ b> A of the second link 105. 114B are configured not to contact the rear end portion 301 of the sliding groove in the sliding locking portion 128.

By adopting the above-described configuration, when the key top 102 is not pressed, the first locking pins 114A and 114B of the second link 105 abut against the front end portion 300 of the locking groove and the key top is at the highest position. Further, when the key top 102 is pressed down, the first locking pins 114A and 114B can be prevented from coming into contact with the rear end portion 301 of the locking groove to prevent breakage or the like.

In addition to the above configuration, as shown in FIGS. 4 and 5, a front end portion 302 and a rear end portion 303 are formed in a sliding groove of a locking member 117 provided on the lower surface of the key top 102. When not pressed, the fourth locking pins 111A, 111B of the first link 104 are brought into contact with the front end portion 302 to restrict the highest position of the key top 102. When the key top 102 is pressed, the fourth locking pins 111A 111B may be configured not to contact the rear end portion 303.

Next, FIG. 17 illustrates the configuration of the guide support member 103. FIG. 17A illustrates FIG.
The first link 104 and the second link 105 are pivotally supported at the pivotal support portion C by the pivot shaft 125. Here, the distance R1 from the third locking pins 113A and 113B (end P in FIG. 17A) of the second link 105 to the shaft support C, and the second locking pins 112A and 112B of the first link 104. The distance R2 from the end portion S in FIG. 17A to the shaft support portion C, and the first locking pins 114A and 114B of the second link 105 (the end portion T in FIG. 17A) to the shaft support portion C. Is configured to be equal to the distance R3. The end portion P, the shaft support portion C, and the end portion T are configured to be points on a straight line.

  Further, the end portions P and S are rotatable points that do not slide in the direction of the arrow X in FIG. 17A, and the end portion P is on the vertical line of the end portion S in a side view (FIG. 17A). Configured to be a point. For this reason, even when the key top 102 is pressed and moved up and down, the position of the key top 102 does not move in the direction of the arrow X, and an accurate key stroke is ensured (described in line X in FIG. 17C). ).

  In addition to this configuration, the distances R1, R2, R3, R4 from the ends P, Q, S, T to the shaft support C are all equal, and the end Q, the shaft support C, and the end S are When configured to be points on a straight line, the key top 102 can always maintain a horizontal state during the up-and-down movement accompanying the key press (described in line H in FIG. 17C).

  By the way, as shown in FIG. 18, when the distance R4 from the end Q to the shaft support C is made longer than the distances R1, R2, R3 from the other ends P, S, T to the shaft support C, the key top It can be set as the structure which inclined 102. FIG. Also in this configuration, even when the key top 102 is pressed and moved up and down, the position of the key top 102 does not move in the direction of the arrow X, and an accurate key stroke is ensured.

  Further, according to this configuration, the inclination angle of the key top 102 can be arbitrarily determined by changing the distance from the end Q to the shaft support C. For this reason, by changing the distance from the end portion Q of the first link 104 to the shaft support C for each row, a different tilt angle may be given to the tilt of the key top 102 for each row in a curved keyboard or the like. It becomes easy.

  Even if the distance R4 from the end Q to the shaft support C is shorter than the distances R1, R2, R3 from the other ends P, S, T to the shaft support C, the key top 102 is similarly Of course, the structure can be inclined.

  FIG. 17B illustrates FIG. With reference to this figure, it will be described that the position of the key top 102 in the arrow Y direction and the arrow R direction in FIG. 17B does not move.

The movement of the second locking pins 112A and 112B and the third locking pins 113A and 113B of both links 104 and 105 in the direction of the arrow Y is engaged by the side surfaces of the key top 102 and the rotation locking portions 115 and 127 of the holder member 107. Or the movement of the fourth locking pins 111A and 111B and the first locking pins 114A and 114B of both links 104 and 105 in the direction of arrow Y is the sliding locking portion of the key top 102 and the holder member 107. Since it is locked by the side surfaces 116 and 128, the movement of the key top 102 in the arrow Y direction is suppressed (described in the Y row in FIG. 17C).
For this reason, even when the key top 102 is pressed and moved up and down, the position of the key top 102 does not move in the direction of the arrow Y, and an accurate key stroke is ensured (described in row Y in FIG. 17C). ).

  In addition, each of the locking pins 111A, 111B, 112A, 112B, 113A, 113B, 114A, 114B is locked by the locking portions 115, 116, 127, 128, so that the key top 102 moves in the direction of arrow R. Is suppressed (described in line R in FIG. 17C).

  With this configuration, when the key top 102 is pressed, the first link 104 rotates downward (rotates clockwise in FIG. 4) around the position of the rotation locking portion 127 of the holder member 107, while the second link 105. Rotates counterclockwise in FIG. 4 about the pivot shaft 125. Then, at the start of pressing of the key top 102, the flat portion 131A on the lower surface of the base 118 near the lower base end 120 in the first link 104 and the base near the lower base end 124 in the second link 105. The flat surface portion 132A of the lower surface 122 abuts against the pressing regions 133 and 134 indicated by hatching in FIG. 12 on the upper surface of the head portion 106A of the rubber spring 106, thereby pressing the rubber spring 106.

  When the pressing amount of the key top 102 increases, the region between the flat portions 131A and 131B and the vicinity of the corner between 132A and 132B comes into contact with the upper surface of the soft rubber spring head 106A.

  Further, when the pressing amount of the key top 102 is increased, the flat surface portion 131B near the upper base end portion 119 in the first link 104 and the flat surface portion 132B near the upper base end portion 123 in the second link 105 are rubberized. As shown in FIG. 12, the pressing areas 133 and 134 are turned upside down as shown in FIG. 12 (the area 133 is an area in the lower right half of the head 106A, the area 134. Is the upper left half area of the head 106A).

  Next, a third embodiment of the present invention will be described with reference to FIG. In this embodiment, the pressing portion 231 formed on the lower surface of the base portion 218 of the first link 204 is formed in a shape in which three flat portions are connected in a convex polygonal shape having a ridge line substantially parallel to the axis of the support hole 221. Although not shown, the second link 205 is also formed with the same multi-plane pressing portion 232.

  In this embodiment, as shown in FIG. 15A, the pressing area 233 by the first link 204 and the pressing area 234 by the second link 205 at the start of pressing the key top 102 are the head 106A of the rubber spring. Although the upper and lower halves of the upper surface are located far away from each other on the left and right, the pressing areas 233 and 234 approach the center from the left and right ends as the pressing amount of the key top 102 increases (FIG. 15). (See (B)), and further divided toward the left and right ends (see FIG. 15C).

  In this way, by forming the pressing portions 231 and 232 in the first link 204 and the second link 205 in the downward convex convex polygonal plane, the upper surface of the head 106A of the rubber spring is made to be the corner of each plane portion. The key pressing feeling is shortened, and the operability of the key, especially tactile (feeling of tactile sensation in which the key operating resistance suddenly changes when the electrical contact is turned on when the key top is pressed) is improved. The operation can be stabilized.

  In addition, since the pressing (contact) area with respect to the upper surface of the head 106A moves symmetrically toward each other in accordance with the pressing input operation of the key top 102, the rubber spring of the rubber spring is moved at any point in the key top stroke. The head 106A can be pressed substantially uniformly with a force that is substantially symmetrical with respect to the top and bottom in FIG. 12 (left and right in FIG. 15), and the buckling deformation of the rubber spring can be generated substantially simultaneously around the cap.

  Instead of the flexible circuit board 109 that forms the switching unit 129, a board such as a membrane switch circuit board may be used. Moreover, in the said Example, although between each plane part was made into the corner | angular part, you may make it connect each plane part with a gentle curved surface.

  FIG. 16 shows the relationship between the load and the stroke amount when the key top is pressed. FIG. 16B is a graph showing data of a conventional key switch device. According to this, when the operator presses the end part (2), (3), (4), (5) of the key top compared to when the operator presses the center (1) of the key top, It can be seen that the load applied is larger and unstable.

  On the other hand, FIG. 16A is a graph showing data of the key switch device of the present invention. According to this, even if the operator presses any part (1), (2), (3), (4), (5) of the key top, the load on the operator is almost uniform. . This means that the key switch device of the present invention always gives the operator a certain feel for every key operation of the operator, and allows the operator to perform smooth key input. Show.

  A key switch device that eliminates the need for a key stem structure, maintains a large keyboard stroke while maintaining a thin keyboard, and has good key input operability with a simple configuration and enables reliable key input. Can be provided.

It is side sectional drawing of the key switch apparatus of 1st Example. It is a top view of one link member of the 1st example. It is a top view of the other link member of the 1st example. It is side sectional drawing of the key switch apparatus of 2nd Example. It is a sectional side view which shows the pressing state of the keytop of 2nd Example. It is a bottom view of a key top. (A) is a top view of the 1st link of 2nd Example, (B) is a top view of the 2nd link of 2nd Example. FIG. 8 is a sectional view taken along arrow VIII-VIII in FIG. 7. It is IX-IX arrow sectional drawing of FIG. It is XX arrow sectional drawing of FIG. It is XI-XI arrow sectional drawing of FIG. It is a top view of a rubber spring and a mounting hole. It is a perspective view of the attachment hole part of a holder member. It is a side view which shows the press part of the 1st link of 3rd Example. (A), (B), and (C) are operation | movement explanatory drawings which show the change of a press area as the pressing amount increases from the pressing start of the keytop of 3rd Example. (A) is a graph which shows the relationship between the load at the time of key depression of the key switch apparatus in this invention, and a key stroke amount, (B) is the relationship between the load at the time of the key depression of the conventional key switch apparatus, and a key stroke amount. It is a graph to show. (A) illustrates FIG. 4, (B) illustrates FIG. 12, and (C) illustrates conditions for preventing the key top from moving in the direction of the arrow when the key is pressed. It is the table shown. Fig. 4 illustrates another embodiment of the present invention.

Explanation of symbols

DESCRIPTION OF SYMBOLS 1 Key top 2,27 Rotation locking part 3,26 Sliding locking part 4,29 Locking hole 5,28 Locking groove 6 Guide support member 7,8 Link member 13,14 3rd locking pin 21, 22 2nd locking pin 15, 16 1st locking pin 23, 24 4th locking pin 25 Holder member 30 Flexible circuit board 31 Rubber spring A Shaft support L Perpendicular 101 Key switch 102 Key top 103 Guide support member 104 1st link 105 and the second link 106 rubber spring 107 holder member 107A mounting hole 109 the flexible circuit board 110 a reinforcing plate 112A, 112B second locking pin 113A, 113B third locking pins 111A, 111B fourth locking pin 114A, 114B first Locking pin 115, 127 Rotation locking part 116, 128 Sliding locking part 118, 122 Base 121 Support hole 125 Pivot shaft 131,132 Press part 133,134 Press area

Claims (1)

Key tops,
A holder member disposed in a lower position of the key top and having a through-hole formed therein;
While having a 1st link member and a 2nd link member, both link members are arrange | positioned in the side view X shape, and it guides and supports the vertical movement of a keytop by connecting the said keytop and a holder member. A guide support member;
A circuit board disposed below the holder member;
A rubber spring that urges the key top upward and performs a switching operation in accordance with the vertical movement of the key top;
A first locking pin formed at a lower end of the first link member;
A second locking pin formed at the lower end of the second link member;
A sliding engagement part integrally formed with the holder member, arranged around the through hole, and slidably engaging the first engagement pin;
In the key switch device, which is integrally formed with the holder member, is arranged around the through hole, and includes a rotation locking portion that rotatably locks the second locking pin.
The rubber spring is placed on the circuit board in the through hole of the holder member, and the upper portion of the rubber spring is connected to the sliding engagement portion and the rotation engagement portion of the holder member through the through hole. Protrudes upward from the top surface of
When the key top is pressed, the upper portion of the rubber spring is pressed through the guide support member, and the rubber spring is deformed accordingly, and the first locking pin is moved to the circuit board within the sliding locking portion. The key switch device is characterized in that it is slid on the top and the second locking pin is rotated by the rotation locking portion.

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