This application is related to Japanese Patent Application No. 2013-087845/2013 filed on Apr. 18, 2013
1. Field of the Invention
The present invention relates to a push switch.
2. Description of the Related Art
There is known a push switch in which a movable board is moved in an operating direction of a knob by a push operation of the knob to cause a movable contact point provided on the movable board to slide on a fixed contact point (for example, Japanese Patent Laid-Open Publication No. 2001-243850).
In a push switch 100 according to the conventional example, a movable board 104 having a movable contact point 104a is provided in a case 101 configured by assembling a cover 102 and a pole board 103 to be movable forward/backward in an operating direction of a knob 107 (upper-lower direction in
The movable board 104 is positioned right under the knob 107 in the case 101, and an upper portion thereof is engaged to leg portions 108A and 108B extending downward from the knob 107 by an urging force acting on the movable board 104 from a spring Sp.
In the push switch 100, when the knob 107 moves downward in the side of the pole board 103 by the push operation of the knob 107, the movable board 104 is also pushed by the leg portions 108A and 108B of the knob 107 to move downward in the side of the pole board 103.
The movable contact point 104a is provided to project from a side face of the movable board 104, and makes push-contact with a fixed contact point 103a by an urging force of an unillustrated spring in a direction vertical to an operating direction of the knob 107, wherein the fixed contact point 103a is arranged to be lateral to the movable board 104.
The fixed contact point 103a is provided on a support wall 109 extending upward from the pole board 103, and is provided along a longitudinal direction (upper-lower direction in the figure) of the support wall 109 over a predetermined length.
Therefore, when the movable board 104 moves downward in the side of the pole board 103 by the push operation of the knob 107, the movable contact point 104a moves downward while sliding on a surface of the fixed contact point 103a.
Here, the support wall 109 is provided with a step portion 109a projecting closer to the movable board 104 than the fixed contact point 103a at a lower portion of the pole board 103 in the side of a bottom wall portion 103c. Therefore, when the knob 107 is pushed down from a reference position showed in
In addition, in the push switch 100, the operation of the knob 107 is detected when the movable contact point 104a gets on the step portion 109a to bring in a non-contact state between the movable contact point 104a and the fixed contact point 103a.
In the push switch 100 according to this conventional example, the movable board 104 (movable contact point 104a) positioned right under the knob 107 is moved forward/backward in the same direction as the operating direction of the knob 107 to connector disconnect the movable contact point 104a and the fixed contact point 103a.
Therefore, since it is necessary to ensure a space for moving the knob 107 and the movable board 104 within the case 101, a thickness of the push switch 100 results in becoming increased in the operating direction of the knob 107.
Therefore, in the push switch in which the movable contact point making contact with the fixed contact point is caused to slide to connect or disconnect the movable contact point and the fixed contact point, it is required to thin the thickness of the push switch in the operating direction of the knob.
Accordingly, the present invention is made in view of the above-described problems in the conventional push switch, and an object of the present invention is to provide a push switch that can thin a thickness of the push switch in an operating direction of a knob.
According to an aspect of the present invention, a push switch comprises a fixed contact point, a movable contact point that movably makes contact with the fixed contact point, and a knob that causes the movable contact point in contact with the fixed contact point to slide thereon by a push operation of the knob, thereby connecting/disconnecting the movable contact point and the fixed contact point, wherein a sliding direction of the movable contact point is set to a radial direction to the push direction of the knob.
According to the aspect of the present invention, since the sliding direction of the movable contact point in contact with the fixed contact point is set to the radial direction of the push direction of the knob, it is not necessary to ensure a space for the movable contact point to slide, in the push direction of the knob. Accordingly, it is possible to thin the thickness of the push switch in the operating direction of the knob as compared to the conventional push switch in which the movable contact point slide in the push direction of the knob.
Other objects, features, and advantages of the present invention will become more apparent from the following detailed description made with reference to the accompanying drawings, in which like parts are designated by like reference numbers and in which:
It is noted that
Hereinafter, an embodiment in the present invention will be explained with reference to the accompanying drawings by taking a push switch provided in a switch device as an example.
Here, in the following explanation, for descriptive purposes, a cover 6-side is described as “upward”, a pole board 7-side is described as “downward”, a push switch 2-side is described as “forward”, and a swinging switch 4-side is described as “backward” in
As shown in
The switch 2 is a push switch (hereinafter, referred to as “push switch 2”) that switches on/off by a push operation of a knob 8, and the push switch 2 is provided with the knob 8, a movable board 9 that is operated by the knob 8, a movable contact point 9a that is provided in the movable board 9, and fixed contact points 7a that are provided in the pole board 7.
The knob 8 is supported by a cylindrical support wall portion 61 projecting upward from an upper surface of the cover 6 to be movable in the upper-lower direction.
In the push switch 2, when the knob 8 is operated to be pushed, the movable board 9 moves in a direction (axis line Y direction) vertical to the operating direction (axis line X direction) of the knob 8 by a leg portion 83 extending from the knob 8, and at this time, when the movable contact point 9a provided on the movable board 9 slides on the upper surface of the fixed contact point 7a, the push switch 2 switches on/off.
As shown in
A guide wall 82 guiding the movement of the knob 8 in the upper-lower direction and the leg portion 83 transmitting the operation of the knob 8 to the movable board 9 are provided inside the peripheral wall portion 811, and the knob 8 is supported by the support wall portion 61 in a state of inserting the support wall portion 61 in the side of the cover 6 between the guide wall 82 and the peripheral wall portion 811.
As shown in
The side wall portions 612 and 613 are provided in parallel to each other, and end portions of the side wall portions 612 and 613 in the backward side are connected to each other by the side wall portion 615. A mounting wall 616 on which a plate spring 26 of a heart cam 25 which will be described later is mounted is provided in a front end of the side wall portion 613 to be in a position offset closer to the inside than the side wall portion 613, and the side wall portion 613 and the side wall portion 614 are connected through the mounting wall 616.
The mounting wall 616 is provided in parallel to the side wall portions 612 and 613, and ensures a space S1 between the side wall portion 612 and the mounting wall 616 to be able to insert the leg portion 83 into, which will be described later and forms a space S2 between the peripheral wall portion 811 of the knob 8 and the mounting wall 616 to be able to accommodate a lock pin 27 of the heart cam 25 and the plate spring 26.
As shown in
A projection 821a is provided in the halfway of the wall portion 821 in the longitudinal direction to project backward in the side of the side wall portion 615. The projection 821a is engaged to a guide groove 615a formed on an inner side surface of the side wall portion 615 in a state where the knob 8 is assembled in the cover 6.
The projection 821a in the side of the knob 8 and the guide groove 615a in the side of the side wall portion 615 are respectively provided along the upper-lower direction.
Therefore, when the knob 8 is pushed to move downward in the side of the pole board 7, the projection 821a moves along the guide groove 615a, and thereby the movement in the backside of the knob 8 in the upper-lower direction is guided.
Wall portions 822 and 823 extend along the side wall portions 612 and 613 inside the side wall portions 612 and 613 of the support wall portion 61, and are provided with opening portions 822a and 823a in central parts thereof in the longitudinal direction to penetrate through the wall portions 822 and 823 in the thickness direction.
The opening portions 822a and 823a are respectively formed to have a predetermined length h (refer to
As shown in
Therefore, when the force of pushing the knob 8 downward in the side of the pole board 7 does not act on the knob 8, the falling-down of the knob 8 from the support wall portion 61 is prevented by engagement of the engagement portions 612b and 613b in the side of the support wall portion 61 to lower edges of the opening portions 822a and 823a (in a case of
It should be noted that since the opening portions 822a and 823a are respectively formed to have a predetermined length h (refer to
As shown in
As shown in
As shown in
The guide projection 83a and the guide groove 83b in the side of the leg portion 83, and the guide groove 612a and the guide projection 614a in the side of the support wall portion 61 are respectively provided in the upper-lower direction. When the knob 8 is pushed to move downward in the side of the pole board 7, the guide projection 83a in the side of the leg portion 83 and the guide projection 614a in the side of the support wall portion 61 respectively move along the guide grooves 612a and 83b, thereby the movement of the leg portion 83 (front side of the knob 8) is guided in the upper-lower direction.
Here, in the switch device 1, the leg portion 83 extending downward in the side of the pole board 7 from the knob 8 moves forward/backward in an axial direction of an axis line X1 (refer to
Therefore, when the leg portion 83 moves in a state of being inclined to the axis line X1 at this time, the tip end portion 831 and a contact point P between the tip end portion 831 and the movable board 9 which will be described later are shifted in a radial direction (axis line Y direction) of the axis line X1. Therefore, a position of the movable board 9 in the axis line Y direction is shifted out of a position in which the movable board 9 should be basically.
In the present embodiment, two guide mechanisms configured by the guide projections (83a and 614a) and the guide grooves (612a and 83b) are provided, which prevents the leg portion 83 from moving downward in the side of the pole board 7 in a state of being inclined to the axis line X1 at a push operation of the knob 8.
As shown in
One end of the spring Sp1 is mounted on the spring support portion 24 to be inserted around it, and the other end of the spring Sp1 is mounted to be inserted around a spring supporting portion 64 formed integrally with the cover 6.
The spring Sp1 is provided along the push direction (axis line X direction) of the knob 8 to exert an urging force in a direction (upper direction in the figure) of causing the knob 8 to fall down from the support wall portion 61 on the knob 8.
The leg portion 83 extending downward in the side of the pole board 7 from the knob 8 is positioned in the forward side of the knob 8 in the front-back direction of the switch device 1.
The leg portion 83 is provided along the push direction (axis line X1 direction) of the knob 8, and is provided in parallel to the spring Sp1 provided along the axis line X.
The leg portion 83 projects closer to the downward side in the side of the pole board 7 than the peripheral wall portion 811, and the tip end portion 831 thereof through which the opening 62 of the cover 6 penetrates is provided with an inclined surface 831a that makes contact with the contact portion 92 of the movable board 9.
The inclined surface 831a is provided at the backside of the leg portion 83 in the front-back direction of the switch device 1, and the inclined surface 831a is inclined by a predetermined angle θ to the operating direction (axis line X1) of the knob 8.
Therefore, the tip end portion 831-side of the leg portion 83 has a width W in the front-back direction of the switch device 1 that is narrower toward the downward side in the side of the pole board 7, and the leg portion 83 causes the inclined surface 831a provided in the tip end portion 831 to make contact with the contact portion 92 of the movable board 9 from the upper side in the upper-lower direction of the switch device 1.
The movable board 9 is provided to be movable forward/backward in a direction (axis line Y direction) vertical to the operating direction (axis line X/X1 direction) of the knob 8 by a terminal holding portion 71. When the leg portion 83 moves in the operating direction (axis line X/X1 direction) of the knob 8, a position of the contact point P between the inclined surface 831a of the leg portion 83 and the contact portion 92 of the movable board 9 changes in the axis line Y direction, and thereby, a position of the movable board 9 in the axis line Y direction changes in association with the operation of the knob 8.
As shown in
The contact portion 92 is formed to project forward from the one end 91a of the main body portion 91, and has a width W2 narrower than a width W1 of the main body portion 91.
As shown in
As shown in
The arm portions 93 are columnar members extending linearly in the longitudinal direction of the main body portion 91, and engagement portions 93a are provided in the tip end portions of the arm portions 93 to project outward from the main body portion 91 in the width direction.
A columnar projection 94 is provided in the other end 91b of the main body portion 91 at the opposite side to the contact portion 92. The projection 94 projects backward of the switch device 1 from the central part of the main body portion 91 in the width direction, and one end of the spring Sp2 is mounted on the outer periphery to be fitted around it.
The other end of the spring Sp2 is mounted to be fitted around a projection 78 provided in a holding portion 77 in the side of the pole board 7, and the spring Sp2 is, when the movable board 9 is assembled in the pole board 7, provided at a compression state between the main body portion 91 and the holding portion 77.
At this time, the movable board 9 is pushed to the forward side of the switch device 1 by the urging force acting from the spring Sp2 to engage the engagement portions 93a of the aforementioned arm portions 93 to engagement grooves 75a of guide plates 75, thus preventing the movable board 9 from falling down from the guide plates 75.
Here, the contact portion 92 of the movable board 9 makes contact with the inclined surface 831a of the leg portion 83 from the axis line Y direction by the urging force acting from the spring Sp2, and the spring Sp2 moves the knob 8 upward in the figure, and at the same time, exerts the urging force in the direction of moving the position of the contact point P between the inclined surface 831a and the contact portion 92 to the forward side (left side in the figure) of the switch device 1.
Therefore, the urging force of the spring Sp2 acts on the forward side of the knob 8, in which the leg portion 83 is provided, in the direction of moving the knob 8 in the upper direction in the figure (direction of causing the knob 8 to fall down from the support wall portion 61).
In the present embodiment, a support wall portion 614b is provided forward of the tip end portion 831 of the leg portion 83 along the tip end portion 831. The support wall portion 614b extends on an extension line of the side wall portion 614 of the support wall portion 61 in the case 5, which prevents the side of the tip end portion 831 of the leg portion 83 from being inclined to the axis line X1 by the urging force of the spring Sp2 causing the contact portion 92 of the movable board 9 to make push-contact with the inclined surface 831a. Further, the support wall portion 614b also acts as a guide at the time the leg portion 83 moves forward/backward in the axis line X1 direction.
As shown in
The movable contact point 9a is formed by bending one sheet of metallic plate, and has a substantial U-letter shape in a cross sectional view. As shown in
One end of a spring Sp3 projecting downward from the spring holding portion 95 makes contact with the central part of the concave portion 9a1 in the width direction, and the other end of the spring Sp3 is inserted in a cylindrical spring holding hole 95b provided in the spring holding portion 95.
The movable contact point 9a is movable in the upper-lower direction by the spring Sp3 accommodated in the spring holding hole 95b, and a lower surface of the movable contact point 9a is caused to make push-contact with the fixed contact points 7a provided in the side of the pole board 7 by an urging force acting from the spring Sp3.
As shown in
The fixed contact points 7a are formed to be integral with the terminal holding portion 71 of the pole board 7 by insert molding, and in the terminal holding portion 71, the fixed contact points 7a are exposed on an upper surface of a projecting portion 73 projecting upward from an upper surface 71a of the terminal holding portion 71.
The terminal holding portion 71 is placed on an upper surface of a lower cover portion 72, and the fixed contact points 7a insert-molded in the terminal holding portion 71 are connected to an unillustrated print board placed on the upper surface of the lower cover portion 72 as similar to other wiring members provided in the terminal holding portion 71.
As shown in
A holding portion 77 holding the other end of the above spring Sp3 is provided to project in the same direction as the projecting portion 73 on an extension line from the backward side (right side in
A step portion 74 projecting closer to the upward side to the knob 8 than the projecting portion 73 is provided in the holding portion 77 side in the projecting portion 73. The step portion 74 extends in the same direction as the fixed contact points 7a between the fixed contact points 7a, 7a and is formed in a rectangular shape in a plan view.
An inclined surface 74a is provided in the end portion of the step 74 at the forward side (left side in the figure), having a height from the projecting portion 73 that is lower toward the forward side of the step portion 74. In a case where the movable board 9 (movable contact point 9a) moves to the side of the holding portion 77 (right side in the figure) by an operation of the knob 8, when the movable contact point 9a gets through the inclined surface 74a on the step portion 74, the movable contact point 9a is arranged in a position away by a predetermined height ha upward from the fixed contact point 7a (refer to
As shown in
The guide plates 75 are provided in parallel to each other along the movement direction (axis line Y direction) of the movable board 9, and are provided linearly in a range from the end portion 71b of the terminal holding portion 71 in the forward side (left side in the figure) to the vicinity of the holding portion 77.
The guide plates 75 are provided to project upward from the terminal holding portion 71 of the pole board 7, and stoppers 76 are provided on the upper end portions of the guide plates 75 for preventing the movable board 9 arranged between the guide plates 75, 75 from falling down to the upward side in the figure.
The stoppers 76 in the guide plates 75 are provided at the backward side thereof in the side of the holding portion 77, and engagement grooves 75a engaging to engagement portions 93a provided in the arm portions 93 of the movable board 9 as described above are provided in the forward side of the guide plates 75 adjacent to the stoppers 76.
Hereinafter, an operation of the push switch 2 will be explained.
As shown in
When the knob 8 moves downward in the side of the pole board 7 from this state by a push operation of the knob 8 (refer to an arrow A1 in the figure), the leg portion 83 of the knob 8 also moves downward in the side of the pole board 7 (refer to an arrow A2 in the figure).
Then, since a width W of the tip end portion 831 of the leg portion 83 is wider toward the upper side in the figure, as the leg portion 83 moves downward in the side of the pole board 7, the contact point P between the inclined surface 831a and the contact portion 92 of the movable board 9 in the movement direction (axis line Y direction) of the movable board 9 moves in the right direction in the figure.
As a result, the movable board 9 is pushed by the leg portion (inclined surface 831a) to move to the side of the holding portion 77 (an arrow A3 direction in the figure), and therefore, the movable contact point 9a provided in the movable board 9 moves in the right direction in the figure (an arrow A4 direction in the figure) while sliding on the upper surface of the fixed contact point 7a.
The step portion 74 is provided in the pole board 7 (terminal holding portion 71) to project closer to the upward side in the side of the knob 8 than the fixed contact point 7a, and this step portion 74 is provided in a position closer to the holding portion 77 between the fixed contact points 7a, 7a. Therefore, the movable contact point 9a that has moved to the right side in the figure by a push operation of the knob 8 finally climbs the inclined surface 74a provided in the step portion 74 to get on the step portion 74. When the movable contact point 9a gets on the step portion 74, the movable contact point 9a is arranged in a position away from the fixed contact point 7a (refer to
Here, in the push switch 2 in the present embodiment, the heart cam 25 is provided in a substantially central part of the leg portion 83 in the longitudinal direction. The heart cam 25 has a cam groove 28 provided in the leg portion 83 and the lock pin 27 that is engaged to the cam groove 28. The lock pin 27 is provided to penetrate through the mounting wall 616 (refer to
In the present embodiment, when the knob 8 is operated to be pushed downward in the side of the pole board 7, the lock pin 27 provided in the mounting wall 616 and the cam groove 28 move relatively in the upper-lower direction (axis line X1 direction), and a contact position of the lock pin 27 with the cam groove 28 changes along a trace shown in an arrow a in
When the push operation of the knob 8 is eliminated after moving the knob 8 downward in the figure, since the knob 8 is urged upward in the figure by urging forces acting from the springs Sp1 and Sp2, the engagement portion 29 of the heart cam 25 is engaged to the lock pin 27 from the lower direction in the figure to restrict the movement of the upper side of the knob 8 (refer to
Therefore, when the knob 8 of the push switch 2 that is in a reference position (refer to
Here, the leg portion 83 of the knob 8 is provided with two guide mechanisms (refer to
When the knob 8 in the operation position shown in
At this time, the position of the lock pin 27 and the engagement portion 29 is shifted in an axial direction of the axis line Y by the inclination of the cam groove 28. Therefore, when the push operation of the knob 8 is released after pushing down the knob 8, the contact position between the lock pin 27 and the cam groove 28 changes along the trace shown in an arrow b in
Thereby, the knob 8 moves in a direction (upper direction in the figure) of falling down from the support wall portion 61 to be back to the reference position shown in
At this time, since the leg portion 83 of the knob 8 moves upward in the figure, the contact point P between the movable board 9 urged by the spring Sp2 and the leg portion 83 moves to the left side in the movement direction (axis line Y direction) of the movable board 9 following the movement of the leg portion 83.
Then, the movable contact point 9a provided in the movable board 9 moves to the left side in the figure while sliding on the upper surface of the step portion 74 (refer to an arrow B2 in the figure). In addition, when the movable contact point 9a reaches a position where the step portion 74 is not provided, the movable contact point 9a slides on the upper surface of the fixed contact point 7a in a state of making push-contact with the fixed contact point 7a by the urging force of the spring Sp3.
In addition, the fixed contact points 7a are communicated through the movable contact point 9a in a point when the movable contact point 9a makes contact with the fixed contact points 7a, thus creating a state where the push switch 2 switches off.
It should be noted that at the time the knob 8 moves from the operation position shown in
In the present embodiment, the urging force of the spring Sp1 acting on the backward side of the knob 8 is set to be substantially the same as the urging force of the spring Sp2 acting on the forward side thereof. Therefore, the knob 8 can move upward in the figure without being inclined to the axis line X1.
As described above, according to the present embodiment, in the push switch 2 in which the push operation of the knob 8 causes the movable contact point 9a making contact with the fixed contact point 7a to slide thereon, thus connecting/disconnecting the movable contact point 9a and the fixed contact point 7a, the sliding direction of the movable contact point 9a is set to the radial direction (axis line Y direction) of the push direction (axis line X, X1 direction) of the knob 8.
According to this configuration, since the sliding direction of the movable contact point 9a making contact with fixed contact point 7a is the radial direction (axis line Y direction) of the push direction (axis line X, X1 direction) of the knob 8, it is not necessary to ensure the space for the movable contact point 9a to slide in the push direction (axis line X, X1 direction) of the knob 8.
Accordingly, the thickness of the push switch 2 in the push direction (axis line X, X1 direction) of the knob 8 can be made thinner than that of the conventional push switch in which the movable contact point slides in the push direction of the knob.
The movable contact point 9a is provided in the movable board 9 that is movable in the radial direction (axis Y direction) of the push direction (axis line X, X1 direction) of the knob 8, and the knob 8 has the leg portion 83 extending in the push direction (axis line X, X1 direction), and the inclined surface 831a (inclined portion) having a width W in the axis line Y direction that is narrower toward the tip end is provided in one side of the tip end portion 831 of the leg portion 83 in the movement direction (axis line Y direction) of the movable board 9. The knob 8 is provided such that the inclined surface 831a makes contact with the movable board 9.
According to this configuration, when the leg portion 83 of the knob 8 moves in the push direction (axis line X, X1 direction) of the knob 8 by the push operation of the knob 8, the contact point P between the inclined surface 831a provided in the leg portion 83 and the movable board 9 displaces in one side in the movement direction (axis line Y direction) of the movable board 9 to move the movable board 9 to the one side.
Accordingly, by a simple configuration that the inclined surface 831a provided in the leg portion 83 is provided to make contact with the movable board 9, the movement of the knob 8 in the push direction (axis line X1 direction) is changed into the movement of the movable board 9 in the radial direction (axis line Y direction) to the push direction to enable the movable contact point 9a making contact with the fixed contact point 7a to slide in the radial direction.
Here, the movable board 9 has the contact portion 92 with the outer periphery of which the inclined surface 831a makes contact, and the outer peripheral surface (contact surface 92a) of the contact portion 92 is formed in an arc shape in a cross sectional view in the axis line Y direction, and the inclined surface 831a makes point-contact with the outer peripheral surface of the contact portion 92.
Thereby, since it is possible to reduce a frictional resistance at the time of moving the movable board 9 by the leg portion 83 (contact surface 831a) that has moved to the operation direction side of the knob 8 by the push operation of the knob 8, it is possible to smoothly perform the push operation of the knob 8 in the push switch 2.
The spring Sp1 (first urging unit) urging the knob 8 in the opposite side to the push direction, and the spring Sp2 (second urging unit) urging the movable board 9 in the other side in the radial direction (axis line Y direction) of the push direction are provided,
wherein the spring Sp1 is provided in one side of the knob 8 in the radial direction for the urging force from the spring Sp1 to act on the one side of the knob 8, and the leg portion 83 is provided on the other side of the knob 8 for the urging force from the spring Sp2 to act on the other side of the knob 8.
According to this configuration, the urging force acting on the one side of the knob 8 in the radial direction is made to be the same as the urging force acting on the other side by adjusting the urging force of the spring Sp1 and that of the spring Sp2, and thereby, it is possible to prevent the knob 8 from moving in a state of being inclined to the push direction at the time the knob 8 moves in the push direction.
Since it is possible to prevent the occurrence of an obstacle in the movement of the knob 8 due to a state where the knob 8 is inclined to the push direction, it is possible to appropriately suppress occurrence of malfunction of the push switch due to occurrence of the obstacle in the movement of the knob.
Further, at the time the knob 8 returns back to the reference position shown in
Further, in a case of the conventional push switch in which the movable board 104 having the movable contact point 104a is moved in the push direction of the knob 107 to cause the movable contact point 104a having made contact with the fixed contact point 103a to slide (refer to
Therefore, a size of the movable board 104 becomes inevitably large for ensuring strength of the movable board 104 to the push forces acting from the leg portions 108A and 108B.
According to the configuration as described above, since the section of the movable board 9 that is pushed by the leg portion 83 is only one section of the contact point 92, a size of the movable board 9 can be made smaller as compared to a case of the conventional push switch. Thereby, the push switch 2 can be downsized as compared to the conventional push switch.
A freedom degree of the layout in the case 5 is improved corresponding to the downsizing of the movable board 9, and also since materials necessary for producing the push switch 2 can be reduced by the downsizing of the case 5 following the downsizing of the movable board 9, it is possible to reduce manufacturing costs.
In addition, a shape, a size and the like of each member are not limited to those illustrated, but may be arbitrarily set within a range where the operational effect of the present invention can be achieved, corresponding to the installation place, the use aspect or the like.
While only the selected embodiment has been chosen to illustrate the present invention, it will be apparent to those skilled in the art from this disclosure that various changes and modifications can be made therein without departing from the scope of the invention as defined in the appended claims. Furthermore, the foregoing description of the embodiment according to the present invention is provided for illustration only, and not for the purpose of limiting the invention as defined by the appended claims and their equivalents.