JP2006331813A - Push-button switch - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To provide a push-button switch which surely prevents intrusion of dust and water into a switch part and the side of a switch driving part over the years without being influenced by a use environment even if it is used for many years, and is optimum as a design-conscious elevator switch. <P>SOLUTION: A seal member 42 includes: a thin movable seal part 42A composed by molding synthetic rubber into a hollow truncated cone shape; a thick base-side seal part 42B formed on a base part of the movable seal part 42A; and a thick tip-side seal part 42C formed at a tip part of the movable seal part 42A. The tip-side seal part 42C is fitted to a seal mounting groove part 47 of a plunger 41 and sandwiched between a seal crimp part 47a of the plunger 41 and a seal crimp part 40a of a push button 40. The base-side seal part 42B is sandwiched between a seal reception part 8A of a base member 5 and a seal retention part 20 of a cover member 6. The seal member 42 is arranged between the inside of a switch body 1 and an insertion part of a push button part 4 inserted into the switch body 1. <P>COPYRIGHT: (C)2007,JPO&INPIT

Description

  The present invention relates to a push button switch used for, for example, an elevator switch which is a direction indicating switch for instructing an elevator raising / lowering direction.

  The installation location of the elevator switch is the wall surface of the platform where people get on and off the elevator and the inner wall of the elevator cage. The push button switch used as this elevator switch is the push button from the mounting hole of the front panel. It is attached to the front panel with the part exposed.

  The push button switch is exposed, and when the elevator is cleaned, etc., between the push button part of the push button switch and the mounting hole of the front panel, the push button part and the cover member of the push button switch Water and dust may intrude through the gap, and the dust and water intrusion may first rust or corrode the switch board surface, and the contact mechanism of the switch may cause poor contact.

  Also, when the elevator is installed outdoors such as at a station, dust enters between the mounting holes on the front panel and the push button part and accumulates inside, causing the push button part to become inoperable and causing a return failure. In addition, when an elevator is installed in a hot spring town, a sulfur component may enter the push button switch and the copper foil of the switch board may be corroded or the switch may be corroded.

  Therefore, there is a conventional push button switch that is not affected by dust even in an environment where a lot of dust is generated. As shown in FIGS. 14 and 15, this push button switch has a switch mounting plate 60, and a key switch 61 and a dustproof / buffer material 64 </ b> A are mounted on the switch mounting plate 60. A resin switch operating shaft 62 is provided at the center of 60 so as to be movable in the vertical direction in FIG. 14, and this switch operating shaft 62 is always urged upward by a spring member (not shown). A key top 63 is fixed to the upper part of the switch operating shaft 62, and a dustproof and cushioning material 64B is provided along the outer periphery of the lower part of the key switch 63. The dustproof / buffer material 64A is brought into contact with the dustproof / buffer material 64B to provide a dustproof effect.

In such a configuration, by pressing the key switch 63, the key switch 63 is turned on via the switch operating shaft 62. In this case, the key top 63 presses the dustproof / buffer material 64B and the dustproof / buffer material 64B. (See Patent Document 1).
JP-A-10-149735

  However, in the above-described conventional push button switch, since the dustproof / buffer material 64A is brought into contact with the dustproof / buffer material 64B to provide a dustproof effect, the switch user can If it is long, or if there is a habit of pushing the key top 63 with a hard object such as a key, a hard object such as a fingernail or key will come off the key top 63 and come into contact with the dustproof and cushioning materials 64A and 64B. As a result, the dustproof effect is reduced, and the contact mechanism of the key switch 63 causes poor contact due to intrusion of dust and water. When there is a problem, and the dustproof and cushioning materials 64A and 64B are discolored after a long period of use, and when used as an elevator switch emphasizing design, the color of the elevating nameplate will appear to change. Cormorant problem there was.

  The present invention has been made in order to improve such conventional problems. The purpose of the present invention is to switch dust and water switches and switch drives regardless of the usage environment even if they are used for many years. It is possible to reliably prevent the intrusion to the side for many years, and to provide a push button switch that is optimal as an elevator switch with an emphasis on design.

  In order to achieve the above object, a push button switch according to the present invention includes a switch body, a switch part housed in the switch body, a switch drive part housed in the switch body and operating the switch part, A push button switch having a push button portion that pushes and activates the switch drive portion, and spans a seal member between the inside of the switch body and the insertion portion inserted into the switch body of the push button portion, and The switch part and the switch drive part are protected against dust and water by a sealing member.

  Since the seal member has such a configuration, the seal member is bridged between the inside of the switch body and the insertion portion inserted into the switch body of the push button unit. If there is a flaw that pushes the push button part with a hard object, hard objects such as fingernails or keys will not come off the push button part and destroy the seal member. Regardless of the environment, it is possible to reliably prevent dust and water from entering the switch unit and the switch drive unit for many years. Further, the first and second dustproof / buffer materials as in the prior art do not change color and the color of the elevating nameplate does not appear to change, which makes it an optimal elevator switch with an emphasis on design.

  The switch body corresponds to, for example, an assembly of a base member and a cover member, and the inside of the switch body corresponds to, for example, a joint portion between the base member and the cover member, and a push button portion and For example, a push button and a plunger interlocked with the push button correspond, and the insertion portion inserted into the switch body of the push button portion corresponds to, for example, a plunger. The switch unit corresponds to, for example, a switch board and a tactile switch that is a switch mounted on the switch board, and the switch drive unit is an operation member that operates the switch by operating a push button unit, for example. This operation member is integrally formed of an elastic plate, and has a switch operating portion provided at a central portion thereof and a plurality of branch portions branched from the central portion.

  Further, the push button switch according to the present invention is the push button switch according to the present invention described above, wherein the seal member has a thin movable seal portion formed by molding an elastic material into a hollow truncated cone shape. The base part of the movable seal part is a thick base side seal part, and the front part of the movable seal part is a thick front side seal part, and the base side seal part is a base constituting the switch body. The front-side seal portion is fitted to an outer peripheral portion of a plunger that constitutes the switch driving portion that operates the switch portion in conjunction with the push button portion. The plunger is configured to be sandwiched between the push button.

  Because of having such a configuration, the base side seal part which is the clamping part on the switch body side of the seal member and the front side seal part which is the clamping part on the push button part side of the seal member are compared with the thin movable seal part. Therefore, the repulsive force of the elastic material can be maintained. For example, when the original thickness is 3 mm, for example, the deformation amount of the front seal portion is 10% ( 0.3mm) elastic deformation is possible, and the deformation amount of the base seal portion is 10% (0.13mm) elastic deformation when the original thickness is 1.3mm, for example, The base seal part is clamped between the base member and the cover member, and the front seal part is fitted to the outer periphery of the plunger, and the plunger and the push button are clamped to improve the sealing performance. Can be made.

  Further, the push button switch according to the present invention is the push button switch according to the present invention described above, wherein the base seal portion has a sandwiching surface in contact with the base member and a sandwiching surface in contact with the cover member. The front seal part has a sandwiching surface in contact with the plunger and a sandwiching surface in contact with the push button, and each of the sandwiching surfaces of the base seal part and the front seal part A protruding portion along the circumferential direction is formed on at least one surface.

  With this configuration, in the case of the base side seal portion, the ridge portion is on the other side, which is a base member or a cover member, and in the case of the front side seal portion, the ridge portion is a plunger or push button. Can be brought into contact with each other to prevent contact with the surface and improve the sealing performance.

  The push button switch according to the present invention is the push button switch according to the present invention described above, wherein the switch body abuts the cover member constituting the switch body on the back surface of the front panel for attaching the push button switch. The seal panel is attached to the surface panel, and a seal ring is interposed between the contact surface portion of the cover member and the surface panel.

  With this configuration, the presence of the seal ring can prevent intrusion of dust and water from the gap between the front panel and the switch body into the switch unit and switch drive unit side. For this reason, the presence of the seal member can prevent dust and water from entering the switch unit and the switch drive unit side, thereby ensuring the dustproof and waterproofing of the push button switch.

  Further, the push button switch according to the present invention is the push button switch according to the present invention described above, wherein a seal ring mounting groove is formed in the contact surface portion, and the seal ring is mounted in the seal ring mounting groove. It is characterized by doing so.

  With such a configuration, the presence of the seal ring can reliably prevent dust and water from entering the switch unit and the switch drive unit side from the gap between the front panel and the switch body.

  According to the push button switch according to the present invention, since the seal member is bridged between the inside of the switch body and the insertion portion inserted into the switch body of the push button portion, the user has a long fingernail. Or when there is a habit of pushing the push button part with a hard object such as a key, it is no longer a hard object such as a fingernail or key coming off the push button part and destroying the seal member. Even if it does not depend on use environment, the penetration | invasion to the switch part and switch drive part side of dust and water can be prevented reliably for many years. Further, the first and second dustproof / buffer materials as in the prior art do not change color and the color of the elevating nameplate does not appear to change, which makes it an optimal elevator switch with an emphasis on design.

  Embodiments of the present invention will be described in detail with reference to the drawings.

  1 is a perspective view of a push button switch according to the present invention, FIG. 2 is a perspective view of a state in which the push button switch is attached to the front panel, and FIG. 3 is a perspective view of a state in which the push button switch is attached to the front panel. 4 is a longitudinal sectional view of the push button switch, FIG. 5 is a perspective view of the exploded state of the push button switch, and FIG. 6 is an exploded state of the base member, the switch portion, the switch driving portion and the plunger portion in the push button switch. 7 is a perspective view of the push button switch, FIG. 7 is a perspective view of the base member, the switch unit, the switch drive unit, and the plunger in an exploded state viewed from diagonally below, and FIG. 8 is the push button switch. FIG. 9 is a perspective view of the base member, the switch portion, the switch drive portion, and the plunger portion in an assembled state, FIG. 9 is a longitudinal sectional view of the seal member, and FIG. It is an enlarged view of the X part.

  As shown in FIG. 5, the push button switch A includes a switch body 1, a switch portion 2 housed in the switch body 1, a switch drive portion 3 housed in the switch body 1 and operating the switch portion 2, And a push button unit 4.

  The switch body 1 includes a base member 5 and a cover member 6. As shown in FIG. 6, the base member 5 has a circular bottom surface portion 5 a and a peripheral wall portion 5 b erected on the periphery thereof, and the bottom surface portion 5 a has a substantially hexagonal opening 7. It is formed. Further, a substantially square switch board mounting portion 8 and a seal receiving portion 8A around the switch board mounting portion 8 are formed on the inner surface side of the bottom surface portion 5a.

  As shown in FIGS. 4 and 6, spring locking projections 9 and stopper insertion portions 10 are provided on the inner surface of the bottom surface portion 5 a at the four corners of the switch board mounting portion 8. The insertion portion 10 is provided with a U-shaped guide portion 11 in plan view, and the guide portion 11 is provided with a plunger stopper 11A. In addition, substrate pressers 12 are provided on the edge portions of the opening 7 that face each other.

  As shown in FIG. 6, the cover engaging portions 13 are formed on the peripheral portion 5 b of the bottom surface portion 5 a at locations where the peripheral portion is divided into four equal parts. A locking projection 15 is provided in the recess 14 formed in the portion 5b.

  As shown in FIGS. 4 and 5, the cover member 6 has a hollow cylindrical cover main body 6A, and a seal ring mounting groove 18 is formed on the outer end surface portion 6a of the cover main body 6A. An internal thread portion 19 is formed on the inner periphery of the cover body 6A. The inner end portion of the cover main body 6A is a seal pressing portion 20. The cover main body 6A is formed with a locking piece portion 21 at a location where the circumferential direction is divided into four equal parts. Locking hole portions 22 are provided at the front portions of these locking piece portions 21.

  As shown in FIGS. 6 and 7, the switch unit 2 unitizes a switch board 25, a tactile switch 26 that is a switch mounted on the switch board 25, and a connector 27 mounted on the switch board 25. It is configured. That is, the switch board 25 has a substantially square shape, and the four corners thereof are cut off, the tactile switch 26 is mounted on the front side of the switch board 25, and the connector 27 is mounted on the back side of the switch board 25. .

  As shown in FIG. 6, the tactile switch 26 has a movable portion 26 </ b> C protruding from an opening 26 </ b> B provided at the top of the switch case 26 </ b> A. A plurality of, for example, four LEDs 33 are mounted on the front side of the switch board 5 so as to be positioned in the four directions of the tactile switch 26.

  As shown in FIGS. 5 to 7, the switch drive unit 3 includes an operation member 34 and a coil spring 35 that is four spring members (in FIGS. 5, 6, and 7, two springs are provided). The member 35 is displayed). The operation member 34 is formed by punching and molding a metal plate having elasticity, for example, a plate thickness of about 0.5 mm, and provided with a projecting switch operating portion 36 for operating the tactile switch 26. It has a central part 34A and four branch portions 37 branched in four directions from the central part 34A, and the whole is substantially cross-shaped. And as shown in FIG. 4, the hole part 38 is formed in the front-end | tip part of each branch part 37. As shown in FIG. An annular spring receiving portion 38 </ b> A is formed in the peripheral portion of the hole portion 38.

  As shown in FIG. 5, the push button portion 4 includes a circular cap-like push button 40, a plunger 41, and a seal member 42. As shown in FIG. 4, the push button 40 has a peripheral wall portion 44 formed at the peripheral portion of the ceiling portion 43, and a flange portion 45 is formed at an end portion of the peripheral wall portion 44. Further, the end surface portion of the push button 40 is a seal crimping portion 40a.

  As shown in FIGS. 6 and 7, the plunger 41 has a hollow cylindrical plunger body 46A and a skirt portion 46B connected to the inner end of the plunger body 46A. A seal mounting groove 47 is formed on the outer periphery of 46A, and the end surface of the seal mounting groove 47 is a seal crimping portion 47a (see FIG. 4). Further, as shown in FIG. 7, the skirt portion 46 </ b> B is provided with insertion portions 48 at locations where the circumferential direction is divided into four equal parts, and projections 49 are provided at the end surface portions of these insertion portions 48. .

  As shown in FIG. 7, the insertion portion 48 is surrounded by an opening portion 50 formed by cutting out the skirt portion 46B, and a piece-like stopper portion 51 located outside the opening portion 50, The stopper 51 is formed integrally with the plunger main body 46A. A claw portion 51A is provided at the tip of the stopper portion 51 so as to protrude outward.

  As shown in FIGS. 4 and 9, the seal member 42 is a thin movable seal portion 42A in which a synthetic rubber (for example, material: industrial rubber NBR or EPDM), which is an elastic material, is formed into a hollow truncated cone shape. The base of the movable seal portion 42A is a thick base side seal portion (a sandwiching portion of the seal member 42 on the switch body 1 side) 42B, and the tip of the movable seal portion 42A is thick. The front seal part (the clamping part of the seal member 42 on the push button part 4 side) 42C.

  The base seal portion 42B has a sandwich surface 52a that contacts the seal receiving portion 8A of the base member 5 and a sandwich surface 52b that contacts the seal pressing portion 20 of the cover member 6, and the front seal portion 42C The plunger 41 has a sandwiching surface 53a in contact with the seal crimping portion 47a and a sandwiching surface 53b in contact with the seal crimping portion 40a of the push button 40, and the sandwiching surfaces 52b and 53b have a circumferential direction. A protruding portion 58 is formed.

  As shown in FIGS. 4 and 6, on the bottom surface portion 5a of the base member 5, the switch substrate 25 is attached to the switch substrate attachment portion 8 and the switch portion 2 is attached. In this case, the base member 5 is attached. A substrate presser 12 provided on the switch presses and fixes the switch substrate 25. As shown in FIG. 4, the switch board 25 closes the opening 7 of the bottom surface portion 5 a, the connector 27 protrudes outward from the opening 7, and the tactile switch 26 is positioned at the center of the base member 5. is doing.

  Also, as shown in FIG. 4, one end (lower end) of the coil spring 35 is locked to the spring locking projection 9 provided on the bottom surface 5a, and the operation member 34 is placed on the tactile switch 26. Thus, the switch operating portion 36 of the central portion 34A of the operation member 34 is in contact with the movable portion 26C of the tactile switch 26. The other end portion (upper end portion) of the coil spring 35 is fitted to the spring receiving portion 28 </ b> A of the four branch portions 37 of the operation member 34.

  As shown in FIG. 4, a plunger 41 is inserted into the base member 5 so as to overlap the operation member 34, and in this case, a protrusion 49 provided on the plunger 41 is a branching portion 37 of the operation member 34. The hole 38 is loosely fitted.

  Further, the stopper portion 51 of the plunger 41 is inserted into the stopper insertion portion 10 via the guide portion 11 of the base member 5. In this case, the plunger 41 is lifted by the spring force of the coil spring 35, so that the claw portion 51 </ b> A of the stopper portion 51 provided on the plunger 41 is caught by the plunger stopper 11 provided on the base member 5.

  As shown in FIG. 4, a cover member 6 is attached to the base member 5. In this case, the four locking pieces 21 provided on the cover member 6 are inserted into the recesses 14 of the cover engaging portion 13 of the base member 5 and are inserted into the locking holes 22 of the locking piece 21. The locking projection 15 is locked.

  Further, as shown in FIG. 10, a seal member 42 is bridged between the inside of the switch body 1 and the insertion site of the push button portion 4 inserted into the switch body 1. That is, the front side seal portion 42C of the seal member 42 is fitted in the seal mounting groove portion 47 of the plunger 41, and the front side seal portion 42C includes the seal pressure bonding portion 47a of the plunger 41 and the seal pressure bonding portion 40a of the push button 40. And the protrusion 58 provided on the clamping surface 53b is deformed into a crushed state. In this case, the deformation amount of the front seal portion 42C can be elastically deformed by 10% (0.3 mm) when the original thickness is 3 mm, for example. Further, in the case of the front side seal portion 42C, the protruding portion 58 abuts against the seal crimping portion 40a to prevent contact with the surface and enhance the sealing performance.

  Further, the base seal portion 42B is sandwiched between the seal receiving portion 8A of the base member 5 and the seal pressing portion 20 of the cover member 6, and the protrusion 58 provided on the sandwiching surface 52b is crushed. It has been transformed into a state. In this case, when the original thickness of the base-side seal portion 42B is, for example, about 1.3 mm, 10% (0.13 mm) elastic deformation thereof is possible. In the case of the base side seal portion 42B, the protrusion 58 abuts against the seal retainer portion 20 to prevent contact with the surface and enhance the sealing performance.

  As described above, the seal member 42 is stretched over the plunger 41 and the base member 5, and the switch member 2 and the switch drive unit 3 are protected from dust and water by the seal member 42.

  Further, as shown in FIG. 4, a push button 40 is put on the plunger 41. The push button 40 is attached by an attachment ring 54 used when the push button switch A is attached to the front panel B. As shown in FIGS. 2 and 4, the mounting ring 54 has a male screw portion 55 and a flange portion 56 on the outer peripheral portion thereof, and has a stopper portion 57 formed of a step portion on the inner peripheral portion thereof. A seal ring 59 is attached to the seal ring attachment groove 18 of the cover member 6.

  2 and 4, the push button 40 is inserted into the circular mounting hole B-1 of the front panel B, the seal ring 59 is brought into contact with the back surface of the front panel B, and the mounting hole B- 1, the mounting ring 54 is inserted, the male thread portion 55 of the mounting ring 54 is screwed into the female thread portion 19 of the cover member 6, and the surface panel B is formed by the flange portion 56 of the mounting ring 54 and the end surface portion of the cover member 6. The push button switch A is attached to the front panel B by holding the pin, and at this time, the push button 40 is lifted via the plunger 41 by the spring force of the coil spring 35, and the flange of the push button 40 is The portion 45 abuts on the stopper portion 57 of the attachment ring 54, and the push button 40 is attached.

  Further, the presence of the seal ring 59 prevents dust and water from entering the switch unit 3 and the switch drive unit 3 from the gap between the front panel B and the cover member 6 of the switch body 1.

  Next, the operation of the push button switch A configured as described above will be described.

  In a state where the push button 40 is not pushed in, as shown in FIG. 11, the plunger 41 is lifted by the spring force of the coil spring 35, and the claw portion 51A of the stopper portion 51 provided on the plunger 41 is moved to the plunger stopper 11A. It is hooked on. The pushing force is not applied to the four branch portions 37 of the operation member 34, and the switch operating portion 36 of the central portion 34 </ b> A of the operation member 34 is in contact with the movable portion 26 </ b> C of the tactile switch 26.

  In this state, as shown in FIG. 12, when a push force is applied to the push button 40 and pushed, the push button 40 moves downward (parallel movement) in FIG. 12 without being biased. Therefore, the plunger 41 is pushed downward against the coil spring 35 and the branching portion 37 of the operation member 34 is pushed downward.

  Accordingly, the branching portion 37 is bent, and the force applied to the branching portion 37 acts on the central portion 34A of the operation member 34, and the switch operating portion 36 pushes the movable portion 26C of the tactile switch 26 to turn on the tactile switch 26. . For example, if the stroke of the branch part 37 becomes 1 mm, the stroke of the switch operating part 36 becomes 0.6 mm, and the tactile switch 26 is sufficiently operated.

  When the push button 40 is released, the plunger 41 is lifted by the restoring force of the branching portion 37 and the spring force of the coil spring 35, and the claw portion 51A of the stopper portion 51 provided on the plunger 41 becomes the plunger stopper 11A. As a result, the branching portion 37 returns to its original state, the pushing force of the switch operating portion 36 to the movable portion 26C is released, and the tactile switch 26 is turned off.

  Further, as shown in FIG. 13, when the push button 40 is corner-pressed (one-press) at the action point P, the push button 40 is biased and moves downward in FIG. For this reason, the action point P side of the plunger 41 is pushed downward against the coil spring 35, and one (or two) of the four branch portions 37 of the operation member 34 is pushed downward to bend. Mu

  Since the branch portion 37 that is not pressed is in contact with the insertion portion 48 of the plunger 41, the force applied to the pressed branch portion 37 acts on the central portion 34 </ b> A of the operation member 34, and the switch operating portion 36 is operated by the tactile switch 26. The switch movable portion 26C is pushed in, and the tactile switch 26 is turned on. For example, when the stroke of the pushed branch portion 37 becomes 1 mm, the stroke of the switch operating portion 36 becomes 0.6 mm, and the tactile switch 26 is sufficiently operated.

  Then, when the corner button of the push button 40 is released, the plunger 41 is lifted by the spring force of the coil spring 35, and the claw portion 51A of the stopper portion 51 provided on the plunger 41 is caught by the plunger stopper 11A. Returns to the original state, and the pushing force of the switch operating portion 36 to the movable portion 26C is released, and the tactile switch 26 is turned off.

  The coil spring 35 adjusts the load of the operation member 34 which is a cross-shaped spring, and strengthens the spring load. Accordingly, since the tip portions of the four branch portions 37 of the operation member 34 are in contact with the coil spring 35, the impact force applied to the push button 40 is absorbed and buffered by the branch portion 37 and the coil spring 35 to the tactile switch 26. Will not be impacted.

  Further, as shown in FIGS. 12 and 13, when the push button 40 is pushed in and the push button 40 is moved downward, the seal member 42 is bent by the thin movable seal portion 42A and the push button 40 moves. Follow.

  As described above, according to the embodiment of the present invention, since the seal member 42 is stretched over the plunger 41 and the base member 5, the user has a long fingernail or a hard object such as a key. If there is a flaw that pushes the push button part, a hard object such as a fingernail or key will not come off the push button part 2 and destroy the seal member 42. For this reason, However, it is possible to reliably prevent dust and water from entering the switch unit 2 and the switch drive unit 3 for many years. Further, the first and second dustproof and cushioning materials as in the prior art do not change color and the color of the elevating nameplate does not appear to change, so that it becomes an optimum elevator switch with an emphasis on design.

  Further, according to the embodiment of the present invention, the base seal part 42B of the seal member 42 and the front seal part 42C of the seal member 42 are thicker than the thin movable seal part 42A. The repulsive force of the elastic material can be maintained, and the deformation amount of the front seal portion 42C can be elastically deformed by 10% (0.3 mm) when the original thickness is 3 mm, for example. Thus, the deformation amount of the base side seal part 42B is 10% (0.13 mm) of elastic deformation when the original thickness is 1.3 mm, for example, and the base side seal part 42B becomes the base member 5. The seal receiving portion 8A of the cover member 6 and the seal pressing portion 20 of the cover member 6 are sandwiched, and the front seal portion 42C is sandwiched between the seal crimping portion 47a of the plunger 41 and the seal crimping portion 40a of the push button 40. Improved sealing performance It can be.

  Further, according to the embodiment of the present invention, in the case of the front side seal portion 42C, the protrusion 58 can contact the seal crimping portion 40a to prevent contact with the surface and improve the sealing performance. In the case of the side seal portion 42B, the protrusion 58 can contact the seal retainer 20 to prevent contact with the surface and improve the sealing performance.

  Further, according to the embodiment of the present invention, the presence of the seal ring 59 prevents dust and water from entering from the gap between the front panel B and the switch body 1 to the switch unit 3 and switch drive unit 3 side. can do. For this reason, the presence of the seal member 42 can prevent dust and water from entering the switch unit 2 and the switch drive unit 3 side, and thus the push button switch is reliably protected against dust and water. Become.

  In the above-described embodiment of the present invention, the protrusions 58 are formed only on the clamping surface 52a of the clamping surfaces 52a and 52b of the base seal part 42B. However, the protrusions are also formed on the clamping surface 52b. The portion 58 may be formed, or the protrusion 58 may be formed on both the clamping surfaces 53a and 53b in the front seal portion 42C.

  According to the push button switch according to the present invention, since the seal member is bridged between the inside of the switch body and the insertion portion inserted into the switch body of the push button portion, the user has a long fingernail. Or when there is a habit of pushing the push button part with a hard object such as a key, it is no longer a hard object such as a fingernail or key coming off the push button part and destroying the seal member. Even if it does not depend on use environment, the penetration | invasion to the switch part and switch drive part side of dust and water can be prevented reliably for many years. In addition, since the first and second dustproof and cushioning materials do not change color and the color of the elevating nameplate does not appear to change, the elevator ascending / descending can be optimized. It is useful as a push button switch or the like used for an elevator switch or the like that is a direction indicating switch for indicating a direction.

1 is a perspective view of a push button switch according to the present invention. It is a perspective view of the state which attaches the same pushbutton switch to a surface panel. It is a perspective view of the state which attached the same pushbutton switch to the surface panel. It is a longitudinal cross-sectional view of the same pushbutton switch. It is a perspective view of the decomposition | disassembly state of the same pushbutton switch. FIG. 5 is a perspective view of a disassembled state of a base member, a switch portion, a switch drive portion, and a plunger portion viewed obliquely from above in the push button switch. FIG. 5 is a perspective view of a disassembled state of a base member, a switch portion, a switch drive portion, and a plunger portion viewed obliquely from below in the push button switch. In the same pushbutton switch, it is a perspective view of an assembly state of a base member, a switch part, a switch drive part, and a plunger part. It is a longitudinal cross-sectional view of a sealing member. It is an enlarged view of the X section of FIG. In the same push button switch, it is a longitudinal cross-sectional view of a state where there is no depression by the push button. FIG. 4 is a longitudinal sectional view of the push button switch in a state where the center of the push button is pushed in. FIG. 4 is a longitudinal sectional view of the push button switch in a state where a push button is pushed into a corner. It is a perspective view of the decomposition | disassembly state of the conventional pushbutton switch. It is a perspective view of the assembly state of the same pushbutton switch.

Explanation of symbols

A Push button switch B Front panel 1 Switch body 2 Switch part 3 Switch drive part 4 Push button part 5 Base member 6 Cover member 8A Seal receiving part 18 Seal ring mounting groove part 20 Seal retainer part 25 Switch board 26 Tactile switch (switch)
26C Movable part 34 Operation member 40 Push button 40a Seal crimping part 41 Plunger 42 Seal member 42A Movable seal part 42B Base side seal part (clamping part on the switch body side of the seal member)
42C Front side seal part (clamping part on the push button part side of the seal member)
47 Seal mounting groove 47a Seal crimping part 49 Protruding part 52a Clamping surface 52b Clamping surface 53a Clamping surface 53b Clamping surface 58 Projection part 59 Seal ring

Claims (5)

A push button comprising a switch body, a switch portion housed in the switch body, a switch drive portion housed in the switch body and operating the switch portion, and a push button portion for pushing the switch drive portion A switch,
A seal member is bridged between the inside of the switch main body and the insertion portion of the push button portion inserted into the switch main body, and the switch portion and the switch driving portion are dustproofed and waterproofed by the seal member. A push button switch characterized by that. The seal member has a thin movable seal portion formed by molding an elastic material into a hollow frustoconical shape, and a base portion of the movable seal portion is a thick base side seal portion, and a tip portion of the movable seal portion Is a thick tip side seal part,
The base side seal portion is sandwiched between a base member and a cover member constituting the switch body, and the front side seal portion is operated by the switch to operate the switch portion in conjunction with the push button portion. The push button switch according to claim 1, wherein the push button switch is configured to be fitted to an outer peripheral portion of a plunger constituting the portion and to be sandwiched between the plunger and the push button. The base side seal portion has a clamping surface in contact with the base member and a clamping surface in contact with the cover member, and the tip side sealing portion contacts the clamping surface in contact with the plunger and the push button. It has a clamping surface, The protrusion part along the circumferential direction is formed in at least one surface of each said clamping surface of the said base side seal part and the said front side seal part, It is characterized by the above-mentioned. Item 3. A push button switch according to item 2. The switch body is attached to the front panel by abutting a cover member constituting the switch body against the back surface of the front panel for attaching the push button switch, and the contact surface portion of the cover member and the front panel A push button switch according to any one of claims 1 to 3, wherein a seal ring is interposed therebetween. 5. The push button switch according to claim 4, wherein a groove portion for mounting a seal ring is formed in the contact surface portion, and the seal ring is mounted in the groove portion for mounting the seal ring.

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