JP2010182695A - Switch mechanism - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To provide a switch mechanism by which rigid impression in operating a switch knob is felt, and overweight (overload) on a switch is reduced. <P>SOLUTION: When a load on the switch 31 applied by movement of an arm part 54 based on pressing operation of an operation part 53 of the switch knob 51 through a plate spring 61 exceeds a previously set load, the plate spring 61 rapidly and elastically deforms in an opposite direction to an operation direction of the switch knob 51, and the load on the switch 31 is reduced. In addition, when the plate spring 61 rapidly deforms, the rigid impression (operational feeling) in operating the switch knob 51 is obtained. <P>COPYRIGHT: (C)2010,JPO&INPIT

Description

  The present invention relates to a switch knob that is at least partially exposed from an opening provided in the case and is supported in the case so as to be operable based on an operation from the outside of the case, and the operation of the switch knob. The present invention relates to a switch mechanism including a switch that is turned on.

  Conventionally, as this type of switch mechanism, for example, a configuration as shown in Patent Document 1 is known. This switch mechanism includes a switch knob that can be pressed from outside the case. The switch knob includes an operation unit for pressing, and the operation unit is exposed from an opening provided in the case. Further, a portion other than the operation portion in the switch knob is accommodated in the case. The switch knob is integrally formed with an arm portion extending laterally. The switch knob is formed in a T shape from the operation portion and the arm portion. One end of the arm is pivotally supported so as to be able to rotate based on the operation of the switch knob, and the other end is a free end for turning on a switch fixed to the inner bottom surface of the case. That is, the arm portion tilts around the support portion when the operation portion is pressed, and the switch is turned on by the free end of the arm portion. Further, the arm portion is not elastically deformed even when the operation portion is operated. For this reason, in the switch mechanism disclosed in Patent Document 1, when the switch fixed to the case is turned on via the arm, all the pressing force from the operation unit is transmitted to the switch. As a result, although a feeling of rigidity (feeling of response) at the time of operation of the switch knob can be obtained, there is a fear that an unlimited load is applied to the switch. For this reason, as a countermeasure against overload on the switch, for example, the following configuration has been considered.

  That is, as shown in FIG. 5, the switch mechanism 100 includes a switch 120 housed in a case 110 and a switch knob 130 that turns on the switch 120 based on an operation from the outside of the case 110.

The case 110 includes a shaft portion 111 that supports the switch knob 130. The case 110 has an opening 112 that exposes a part of the switch knob 130.
The switch knob 130 includes an operation unit 131 exposed from the opening 112. In the switch knob 130, an elastic leaf spring 132 is formed integrally with the operation portion 131 so as to extend laterally. The switch knob 130 is formed in a T shape from the operation portion 131 and the leaf spring 132. One end of the leaf spring 132 is rotatably supported by the shaft portion 111, and the other end is a free end. By the pressing operation of the operation part 131, the free end side of the leaf spring 132 tilts about the shaft part 111. A substrate 113 is fixed to the inner bottom surface of the case 110, and the switch 120 is fixed on the substrate 113. The switch 120 is arranged in the case 110 so as to be on a rotation locus on the free end side of the switch knob 130.

  When the switch 120 is turned on, the operation unit 131 is pressed. As a result, as indicated by a two-dot chain line in FIG. 5, the switch knob 130 a rotates about the shaft portion 111 of the leaf spring 132, and the switch 120 is moved by the tip of the leaf spring 132 along with the turning operation. When pressed, the switch 120 is turned on. Further, when the operation portion 131 is pressed, as shown by a two-dot chain line in FIG. 5, the leaf spring 132 of the switch knob 130 b protrudes from the switch knob 130 b and the inner bottom surface of the case 110. It bends by the overstroke provided between the two. The leaf spring 132 is bent by the overstroke, so that the load applied to the switch 120 is relieved.

JP 2004-220924 A

  By the way, the switch mechanism 100 having the above configuration is configured such that the overload applied to the switch 120 is relieved (absorbed) when the leaf spring 132 is bent by the overstroke. For this reason, the switch 120 is protected to some extent from the overload, but on the other hand, there is a problem that the feeling of rigidity (feeling of response) is impaired when the operation unit 131 is pressed. In other words, in order to obtain a feeling of rigidity, the elastic coefficient of the leaf spring 132 may be increased to make it difficult to bend, but the switch mechanism 100 suppresses overload to the switch 120 by bending the leaf spring 132. In terms of configuration, it was difficult to obtain rigidity. Accordingly, there has been a demand for a switch mechanism 100 that can alleviate overload on the switch 120 and can provide a sense of rigidity with respect to the operation of the switch knob 130.

  The present invention has been made in view of the above problems, and it is an object of the present invention to provide a switch mechanism capable of obtaining a sense of rigidity when operating a switch knob and reducing an overload applied to the switch.

  In order to solve the above problems, the invention according to claim 1 is characterized in that at least a part of the invention is exposed from an opening provided in the case and is operable based on an operation from the outside of the case. A switch knob, and a switch mechanism that is housed in the case and that is turned on based on the operation of the switch knob, wherein the switch has an operation direction of the switch knob in the case. The load applied by the operation of the switch knob based on the operation from the outside is fixed to the portion of the inner bottom surface of the case facing the substrate that is fixed to the substrate that is movable in the same direction. The gist of the invention is to provide an elastic member that suddenly elastically deforms in the operation direction of the switch knob based on the same operation.

  According to a second aspect of the present invention, in the switch mechanism according to the first aspect, one end of the switch knob is rotatably supported by a support portion in the case, and the other end is mounted with the elastic member. And an operating part that is exposed from the opening of the case and that performs a pressing operation from the outside of the case, and the operating part includes the support part and the operating part. The gist is to be provided in between.

  According to a third aspect of the present invention, in the switch mechanism according to the second aspect, when the switch knob is not operated, an inner portion of the case is provided between the arm portion of the switch knob and the inner side surface of the case. The gist is that an elastic absorbing member is interposed so as to be in close contact with the side surface and the arm portion of the switch knob.

(Function)
According to the first aspect of the present invention, when the load applied to the switch by the operation of the switch knob based on the operation from the outside exceeds a preset load, the elastic member suddenly elastically deforms in the operation direction of the switch knob. To do. The substrate and the switch move in the operation direction along with the elastic deformation of the elastic member. Thus, the load applied to the switch is relaxed. Further, when the elastic member is suddenly deformed, it is possible to obtain a feeling of rigidity (operation feeling) in the operation of the switch knob. For this reason, it is possible to obtain a sense of rigidity when operating the switch knob, and to reduce the overload applied to the switch.

  According to the invention of claim 2, in addition to the operation of the invention of claim 1, the switch knob rotates (tilts) with the support portion as a fulcrum by operating the operation portion, and the action portion The switch is turned on via an elastic member attached to the. That is, in the switch knob, the support portion, the operation portion, and the action portion respectively correspond to a fulcrum, a force point, and an action point in the “lever principle”. Here, since the operation part of the switch knob is provided between the support part and the action part, the amount of movement in the action part of the arm part with respect to the operation amount (stroke amount) when operating the operation part is small. growing. For this reason, the switch can be turned on with a small operation amount. Therefore, the operability is improved.

  According to invention of Claim 3, in addition to the effect | action of Claim 2, it is prevented that the inner surface of the said case and the arm part of a switch knob mutually contact | abut. For example, when the switch knob vibrates due to vibration or the like, the vibration is absorbed by the absorbing member even in a state where the arm portion and the case are moved in a direction approaching each other. For this reason, it is possible to suppress abnormal noise caused by vibration of the switch knob or the like.

  According to the present invention, it is possible to obtain a sense of rigidity when operating the switch knob, and to reduce an overload applied to the switch.

(A) is sectional drawing which shows the release position in the switch mechanism of 1st Embodiment, (b) is sectional drawing which shows the same pressing position, (c) is sectional drawing which shows the elastic deformation position in the same disk spring. The perspective view which shows the relationship between the disc spring and switch in 1st Embodiment. (A) is sectional drawing which shows the release position in the switch mechanism of 2nd Embodiment, (b) is sectional drawing which shows the elastic deformation position in the press position and a disc spring. (A) is sectional drawing which shows the release position in the switch mechanism of another embodiment, (b) is sectional drawing which shows the elastic deformation position in the press position and a disc spring. Sectional drawing which shows the conventional switch mechanism.

(First embodiment)
Hereinafter, a first embodiment (reference example) in which the present invention is embodied in a switch mechanism will be described with reference to FIGS. 1 and 2.

  As shown in FIG. 1A, the switch mechanism 1 includes a switch 31 housed in a case 10 and a switch knob 51 that turns on the switch 31 based on an operation from the outside of the case 10. .

  The case 10 includes a case main body 11 to which the switch 31 is fixed, and a lid 21 having an opening 22 through which a part of the switch knob 51 is exposed. The case 10 has a box shape by combining the case main body 11 and the lid 21.

  The case body 11 is formed with a protruding portion 12 that protrudes perpendicularly from the inner bottom surface of the case body 11. The upper surface of the protrusion 12 is a flat mounting surface 13, and the substrate 14 is mounted on the mounting surface 13. A switch 31 is disposed on the upper surface of the substrate 14. In addition, a stopper 15 is formed on the case body 11 so as to protrude in parallel with the protruding portion 12.

  The lid body 21 includes an insertion port 23 into which the case main body 11 is fitted, and the insertion port 23 is formed in parallel with the opening 22. The inner surface of the lid 21 is fixed in close contact with the outer surface of the case body 11. A bearing portion (not shown) that supports the switch knob 51 is provided on the inner surface of the lid 21.

  The switch 31 includes a switch body portion 32 fixed to the upper surface of the substrate 14 and a movable portion 33 that is turned on based on the operation of the switch knob 51. The movable portion 33 is provided with a spring member (not shown), and can be linearly reciprocated in a protruding and retracting manner with respect to the switch main body portion 32. When the movable portion 33 is retracted into the switch main body 32 against the elastic force of the spring member based on the external pressing operation (the pressing position shown in FIG. 1B), the external pressing operation is released. The spring member automatically returns to the original position (the release position shown in FIG. 1A) by the biasing force of the spring member. The pressing position in the movable portion 33 is set to a position where the movable portion 33 is restricted in a state in which the movable portion 33 slightly protrudes from the switch main body portion 32. At this time, a contact portion (not shown) in the movable portion 33 is in contact with the contact of the switch body portion 32. In this state, the switch 31 is turned on (energized state).

  The switch knob 51 includes a support portion 52 supported by the bearing portion of the lid body 21, an operation portion 53 operated through the opening 22, and an arm portion that transmits the pressing force of the operation portion 53 to the switch 31. 54. The base end of the arm portion 54 is supported by the support portion 52 so as to be capable of rotating, and the distal end is a free end. In addition, a disc spring receiving portion 55 as a cylindrical action portion is formed at the tip of the arm portion 54 so as to face the protruding portion 12. The disc spring receiving portion 55 is provided with a disc spring 61 as an elastic member.

(Belleville spring 61)
As shown in FIG. 2, the disc spring 61 includes a base end portion 62 that is supported by the disc spring receiving portion 55, and a deformation portion 63 that is integrally connected to the base end portion 62. An outer peripheral surface 63 a of the deformable portion 63 is connected to a connecting surface 64 formed on the base end portion 62 on the side opposite to the disc spring receiving portion 55. The proximal end portion 62 is formed in a cylindrical shape, and the deformable portion 63 is formed in a truncated cone shape whose diameter decreases toward the distal end. That is, the outer peripheral surface 63a of the deformable portion 63 is inclined from the base end toward the tip. The outer diameter (inner diameter) of the base end of the deforming part 63 is smaller than the outer diameter (inner diameter) of the base end part 62. For this reason, when a load is applied in the direction from the distal end to the proximal end of the deformable portion 63, the outer peripheral surface 63a does not undergo elastic deformation until a certain amount of load is applied, but when a preset load is applied. It becomes elastically deformable inward.

  The side of the deformable portion 63 opposite to the base end portion 62 is closed by a circular contact surface 65, and the contact surface 65 contacts the movable portion 33 of the switch 31 based on the operation of the switch knob 51. . The switch 31 is turned on when the contact surface 65 of the disc spring 61 moves in the operation direction based on the pressing operation of the switch knob 51. In this state, the surface of the movable portion 33 is disposed so as to contact the center of the contact surface 65. Further, the surface area A (shaded portion A shown in FIG. 2) of the contact surface 65 is larger than the surface area B (hatched portion B shown in FIG. 2) that contacts the contact surface 65 of the movable portion 33 of the switch 31. Is set to For this reason, when a load is applied from the abutment surface 65 toward the base end 62 of the disc spring 61, the elastic deformation does not occur up to a preset load. When the load is exceeded, it suddenly elastically deforms inward. The preset load is set to be larger than the elastic force of the spring member in the movable portion 33 of the switch 31. For this reason, as shown in FIG. 1B, the disc spring 61 is not elastically deformed even when the movable portion 33 of the switch 31 is turned on.

  In the state where the movable portion 33 of the switch 31 is turned on, the disc spring 61 is further pressed, and the inward direction of the disc spring 61 from the contact surface 65 (the direction opposite to the operation direction in FIG. 1A). When a load more than a preset value is applied to), it is elastically deformed in the direction opposite to the operation direction. In this way, an elastic material that is different from one that gradually deforms in response (proportional) to a given load, such as a proportionally deformed sponge, is employed. When the contact surface 65 of the disc spring 61 is elastically deformed, the contact surface 65 is drawn inward from the connecting surface 64 (elastic deformation position shown in FIG. 1C).

(Stopper 15)
As shown in FIG. 1C, the stopper 15 protrudes from the inner bottom surface of the case main body 11, and the protruding height is formed higher than the protruding portion 12. Further, the height of the protrusion is such that the arm portion 54 of the switch knob 51 is regulated by the stopper 15 and the deformed portion 63 of the disc spring 61 is deformed inward, so that the disc spring 61 ( The connecting surface 64) is set so as not to contact the switch body 32. The stopper 15 is formed directly below the opening 22 and is spaced apart from the protrusion 12 by the length from the disc spring receiving portion 55 to the operation portion 53 of the switch knob 51. That is, since the stopper 15 is formed directly below the operation portion 53 of the switch knob 51, the arm portion 54 is bent even when the switch knob 51 is pressed and an overload is applied via the arm portion 54. It is not to stop. In the present embodiment, the movable portion 33 of the switch 31 is set to a position that stops just at the pressing position while the switch knob 51 is regulated by the stopper 15. The movable portion 33 of the switch 31 can further move inward of the switch main body 32 until a limit load that the switch 31 can withstand is applied. That is, when a load exceeding a preset value is applied to the switch knob 51, the disc spring 61 is first elastically deformed. When the load is further applied, the switch knob 51 itself is regulated by the stopper 15. It has come to be. In this way, the switch 31 can be protected from overload based on the pressing operation of the switch knob 51.

(Absorbing member 71)
The switch knob 51 is provided with a flat absorbent member 71 formed of an elastic resin material or the like. The absorbing member 71 is disposed so as to contact the inner top surface side of the lid 21 in the arm portion 54 and the proximal end portion of the operation portion 53. The absorbing member 71 moves as the switch knob 51 rotates, and comes into contact with the inner top surface of the lid 21 when the switch knob 51 is not operated.

(Operation of the first embodiment)
Next, the usage aspect of the switch mechanism 1 comprised like the said embodiment is demonstrated.
“Release position (see FIG. 1A) → pressing position (see FIG. 1B)”
As shown in FIG. 1A, when the operation portion 53 of the switch knob 51 is pressed in the operation direction, the arm portion 54 rotates about the support portion 52. As a result, the arm portion 54 presses the movable portion 33 of the switch 31 via the disc spring 61. At this time, the movable portion 33 moves inward of the switch main body portion 32 against a biasing force of a spring member (not shown). And as shown in FIG.1 (b), when the said contact part of the movable part 33 contacts the said contact in the switch main-body part 32, the switch 31 will be in an ON state. At this time, the disc spring 61 moves to the pressing position of the movable portion 33 of the switch 31 without elastic deformation.

“Pressing position → Elastic deformation position (see FIG. 1C)”
If the pressing operation of the operation portion 53 is further continued in the state where the switch 31 is in the pressing position, the movement of the movable portion 33 of the switch 31 is restricted, and therefore, the contact surface 65 of the disc spring 61 from the surface of the movable portion 33. Is given a load. As shown in FIG. 1C, when the load exceeds a preset load, the deformed portion 63 of the disc spring 61 is suddenly elastically deformed in a direction opposite to the operation direction of the operation portion 53. The abutment surface 65 of the deformed portion 63 that has been elastically deformed is deformed to a position where it enters the inside of the base end portion 62 rather than the connecting surface 64. At this time, the contact surface 65 vigorously moves inward of the base end portion 62, so that a sense of rigidity (operation feeling) is obtained.

  The disc spring 61 (connection surface 64) stops at a position where it does not contact the switch main body 32 by the stopper 15. Further, in this state, the arm portion 54 of the switch knob 51 cannot move the arm portion 54 with respect to the operation direction beyond the state by the stopper 15, and the switch 31 (switch body portion 32) Overload is not applied. Thus, the switch 31 can be protected from overload.

"Elastic deformation position → Release position"
When the pressing operation of the operation portion 53 is released, the arm portion 54 moves in the direction opposite to the operation direction by the elastic force of the disc spring 61 and the biasing force of the movable portion 33. When the deformed portion 63 and the movable portion 33 of the disc spring 61 are returned to the original position, the switch knob 51 is returned to the release position of the switch 31 as shown in FIG. At this time, even if the deformed portion 63 is vigorously restored to its original state, the absorbing member 71 is interposed between the arm portion 54 and the lid body 21, so that the arm portion 54 is attached to the lid body 21. It is suppressed that it contacts. As a result, the abnormal noise etc. which generate | occur | produce due to the arm part 54 contacting the cover body 21 are suppressed.

(Effect of 1st Embodiment)
Therefore, according to the switch mechanism 1 of the first embodiment, the following effects can be obtained.

  (1) When the load applied to the switch 31 via the disc spring 61 by the operation of the arm portion 54 based on the pressing operation of the operation portion 53 of the switch knob 51 exceeds a preset load, the disc spring 61 The load applied to the switch 31 due to sudden elastic deformation in the direction opposite to the operation direction is alleviated. Further, when the disc spring 61 is rapidly deformed, it is possible to obtain a feeling of rigidity (operation feeling) in the operation of the switch knob 51. For this reason, it is possible to obtain a sense of rigidity when the switch knob 51 is operated, and to reduce overload (overload) applied to the switch 31.

  (2) The load applied to the switch 31 by the operation of the switch knob 51 based on the pressing operation of the operation portion 53 of the switch knob 51 is applied as a reaction force (load from the surface of the switch 31 toward the contact surface 65 of the disc spring 61). It concentrates on the part which contacts the contact surface 65. That is, a load (stress) is concentrated on a small range of the contact surface 65 of the disc spring 61 from the surface of the movable portion 33 of the switch 31. For this reason, the disc spring 61 is easily elastically deformed, and the overload applied to the switch 31 based on the operation of the switch knob 51 can be efficiently reduced.

  (3) The arm portion 54 of the switch knob 51 is regulated by the stopper 15 provided on the inner bottom surface of the case 10 before an overload is applied to the switch 31. At this time, the movable portion 33 of the switch 31 is held at the pressed position while the arm portion 54 is regulated by the stopper 15. That is, in this state, since the movable portion 33 of the switch 31 is within the movable range, an overload from the switch knob 51 is not applied to the switch 31. For this reason, the switch 31 can be protected from an overload applied by the operation of the switch knob 51 based on the pressing operation of the operation unit 53.

  (4) The switch knob 51 rotates (tilts) with the support portion 52 as a fulcrum when the operation portion 53 is operated, and the switch 31 is operated via the disc spring 61 mounted on the disc spring receiving portion 55. Operates on. That is, in the switch knob 51, the support portion 52, the operation portion 53, and the disc spring receiving portion 55 correspond to the fulcrum, the force point, and the action point in the “lever principle”, respectively. Here, since the operation part 53 of the switch knob 51 is provided between the support part 52 and the disc spring receiving part 55, it is an arm part with respect to the operation amount (stroke amount) when operating the operation part 53. The amount of movement of the 54 disc spring receiving portions 55 increases. For this reason, the switch 31 can be turned on with a small operation amount. Therefore, the operability is improved.

  (5) The switch knob 51 is provided with an absorbing member 71 so as to come into contact with the inner top surface side of the lid 21 in the arm portion 54 and the proximal end portion of the operation portion 53. This prevents the inner surface of the case 10 and the arm portion 54 of the switch knob 51 from coming into contact with each other. For example, when the switch knob 51 vibrates due to vibration or the like, the vibration is absorbed by the absorbing member 71 even in a state where the arm portion 54 and the case 10 are moved in a direction approaching each other. Therefore, it is possible to suppress noise generated due to vibration of the switch knob 51 or the like.

(Second Embodiment)
Hereinafter, a second embodiment in which the present invention is embodied in a switch mechanism will be described with reference to FIG. The switch mechanism according to this embodiment is different from the first embodiment in the arrangement positions of the switch knob and the disc spring. Therefore, the same reference numerals are given to the same member configurations as those of the switch mechanism 1 of the first embodiment, and redundant description thereof is omitted.

  As shown in FIG. 3A, a bulging portion 56 that protrudes toward the inner bottom surface of the case main body 11 is formed on the opposite side of the arm portion 54 of the switch knob 51 from the support portion 52. The bulging portion 56 has a shape that rises like a dome. The bulging portion 56 presses the movable portion 33 of the switch 31 based on the pressing operation of the operation portion 53.

  A disc spring 61 is disposed on the inner bottom surface of the case body 11. The disc spring 61 is disposed such that the contact surface 65 of the disc spring 61 faces the inner top surface of the lid body 21. For this reason, the deformation | transformation part 63 of the disc spring 61 deform | transforms in the operation direction. The substrate 14 is placed on the contact surface 65 of the deformable portion 63, and the switch body 32 of the switch 31 is placed on the substrate 14. That is, the bulging portion 56 of the switch knob 51, the movable portion 33 of the switch 31, the switch body portion 32, the substrate 14, and the disc spring 61 are arranged in this order from the inner top surface side of the lid body 21. The switch 31 and the substrate 14 can move between a release position shown in FIG. 3A and an elastic deformation position shown in FIG. Further, the disc spring 61 is maintained without being elastically deformed in a state in which the movable portion 33 of the switch 31 is turned on to the pressing position by the bulging portion 56.

  When the movable portion 33 of the switch 31 is turned on and a load greater than a preset value is applied from the switch knob 51 to the operation direction, the deforming portion 63 of the disc spring 61 is elastically abrupt in the operation direction. Deform. At this time, the contact surface 65 of the disc spring 61 is elastically deformed and is drawn inward from the connecting surface 64 (elastic deformation position shown in FIG. 3B). Further, along with the deformation of the deforming portion 63 of the disc spring 61, the substrate 14 and the switch 31 placed on the contact surface 65 of the deforming portion 63 move in the operation direction. The substrate 14 and the switch 31 are movable to a position where the substrate 14 contacts the connecting surface 64 of the disc spring 61. The substrate 14 and the switch 31 are supported by a guide (not shown) so as to be movable only in the operation direction and in the direction opposite to the operation direction. In a state where the substrate 14 is in contact with the connection surface 64 of the disc spring 61, the arm portion 54 of the switch knob 51 is restricted by the stopper 15 so that the arm portion 54 cannot move in the operation direction beyond this state.

(Operation of Second Embodiment)
Next, the usage aspect of the switch mechanism 1 comprised like the said embodiment is demonstrated.
As shown in FIG. 3A, when the operation portion 53 of the switch knob 51 is pressed while the switch 31 is in the release position, the arm portion 54 rotates around the support portion 52. As a result, the bulging portion 56 of the arm portion 54 turns on the switch 31 based on the pressing operation from the operation portion 53. Then, the bulging portion 56 presses the movable portion 33 of the switch 31. Then, as shown in FIG. 3B, when the contact portion (not shown) of the movable portion 33 comes into contact with the contact in the switch main body portion 32, the switch 31 is turned on. Thus, the movable part 33 of the switch 31 can be moved to the pressed position. At this time, elastic deformation of the disc spring 61 does not occur.

  If the pressing operation of the operation portion 53 is further continued in the state where the switch 31 is in the pressing position, the movement of the movable portion 33 of the switch 31 is restricted, so that a load is applied to the contact surface 65 of the disc spring 61. . When the load exceeds a preset load, the deformed portion 63 of the disc spring 61 is elastically deformed in the same direction as the operation direction of the operation portion 53. The abutment surface 65 of the deformed portion 63 that has been elastically deformed is deformed to a position where it enters the inside of the base end portion 62 rather than the connecting surface 64. At this time, the substrate 14 and the switch 31 placed on the contact surface 65 move in the operation direction along with the deformation of the deforming portion 63 of the disc spring 61, and the substrate 14 stops at a position where it abuts on the connection surface 64 of the disc spring 61. (See FIG. 3B). At this time, the arm portion 54 is regulated by the stopper 15, and the arm portion 54 cannot be moved in the operation direction beyond this state. For this reason, an overload is not applied to the switch 31 (switch body 32). Thus, the switch 31 can be protected from overload.

(Effect of 2nd Embodiment)
(6) When the load applied to the switch 31 by the operation of the arm portion 54 based on the pressing operation of the operation portion 53 of the switch knob 51 exceeds a preset load, the disc spring 61 is in the same direction as the operation direction of the switch knob 51. Suddenly elastically deformed. At this time, the substrate 14 and the switch 31 placed on the contact surface 65 move together with the deformation of the deformation portion 63 of the disc spring 61. In this way, the load applied to the switch 31 is relaxed. Further, when the disc spring 61 is rapidly deformed, it is possible to obtain a feeling of rigidity (operation feeling) in the operation of the switch knob 51. For this reason, it is possible to obtain a sense of rigidity when the switch knob 51 is operated, and to reduce overload (overload) applied to the switch 31.

(Another embodiment)
In addition, you may change each said embodiment as follows.
In the switch mechanism 1 of each of the above embodiments, a single hinge mechanism that pivotally supports one end of the switch knob 51 and rotates the switch knob 51 is employed, but the switch mechanism is not limited to the single hinge mechanism. That is, as shown in FIGS. 4A and 4B, a switch mechanism 1 in which the entire switch knob 51a slides only in the operation direction or the counter-operation direction may be employed. In such a configuration, a cylindrical disc spring receiving portion 55a is formed immediately below the operation portion 53a of the switch knob 51a, and the disc spring 61 is disposed in the disc spring receiving portion 55a. Further, the outer wall of the disc spring receiving portion 55a is formed so as to protrude from the connecting surface 64 of the disc spring 61 toward the inner bottom surface side of the case body 11, and this protruding outer wall forms the first stopper 15a. A second stopper 15b is formed to project from the inner bottom surface of the case body 11 so as to face the first stopper 15a. The first stopper 15a and the second stopper 15b are pressed so that the switch knob 51 is pressed so that the disc spring 61 is elastically deformed and the movable portion 33 of the switch 31 has just reached the pressing position. The lengths of the first stopper 15a and the second stopper 15b are set. Further, an absorbing member 71a is disposed on the inner top surface side of the lid 21 in the switch knob 51a. In the case of such a configuration, the same effects as the effects (1) to (3) and (5) can be obtained.

  In each of the above embodiments, the disc spring 61 is used as the elastic body. However, the elastic force is suddenly deformed with a preset load as a boundary, and the load applied to the switch 31 is reduced based on the operation of the switch knob 51. Any configuration that deforms may be used. For example, the disc spring 61 may be deformed into a dome shape, or the deforming portion 63 may be integrally formed vertically between the connecting surface 64 and the contact surface 65. Further, the disc spring 61 may be formed of a rubber material or a resin material. By doing so, it is possible to suppress sound generated during elastic deformation.

  In the first embodiment, the surface area A of the contact surface 65 of the disc spring 61 is formed to be larger than the surface area B of the movable portion 33. However, the same area may be used, or the contact surface The surface area A of 65 may be formed to be narrower than the surface area B of the movable portion 33.

  In the first embodiment, the surface of the movable portion 33 is disposed so as to be in contact with the center of the contact surface 65, but it is not always necessary to be disposed so as to be in contact with the center.

  DESCRIPTION OF SYMBOLS 1 ... Switch mechanism, 10 ... Case, 14 ... Board | substrate, 15 ... Stopper, 15a ... 1st stopper, 15b ... 2nd stopper, 22 ... Opening part, 31 ... Switch, 33 ... Movable part, 51, 51a ... Switch knob, 52 ... support part, 53, 53a ... operation part, 54 ... arm part, 55, 55a ... disk spring receiving part (action part), 61 ... disk spring (elastic member), 65 ... contact surface, 71, 71a ... absorption Element.

Claims (3)

A switch knob that is at least partially exposed from an opening provided in the case and is supported in the case so as to be operable based on an operation from the outside of the case; A switch mechanism comprising a switch that is turned on based on the operation of
In the case, the switch is fixed to a board provided to be movable in the same direction as the operation direction of the switch knob,
The portion of the inner bottom surface of the case facing the substrate is suddenly elastic in the operation direction of the switch knob based on the same operation with the load applied by the operation of the switch knob based on the operation from the outside as a boundary. A switch mechanism characterized in that a deformable elastic member is provided. The switch mechanism according to claim 1,
One end of the switch knob is rotatably supported by a support portion in the case, and the other end is exposed from an arm portion provided with an action portion for mounting the elastic member, and an opening portion of the case. And an operating portion that performs a pressing operation from the outside of the case, and the operating portion is provided between the support portion and the action portion. The switch mechanism according to claim 2,
When the switch knob is not operated, the absorbent member has elasticity so as to be in close contact with the inner surface of the case and the arm portion of the switch knob between the arm portion of the switch knob and the inner surface of the case. A switch mechanism characterized by interposing.

Images