阅读说明：本技术 翘板开关 (Rocker switch ) 是由 桥本真 大塚真人 于 2020-09-14 设计创作，主要内容包括：提供翘板开关,能够在不导致外观恶化和大型化且不受到多余的反作用力的影响的情况下容易地将操作载荷设定为设计值。翘板开关(1)构成为具有：按钮(2),其在被操作输入时进行摆动；外壳(3),其对按钮进行支承；一对开关(5),它们在外壳内相对于按钮的中央部设置于两端部侧；橡胶接触件(施力部)(6),其对按钮的两端部朝向非操作位置施力；一对操作输入部(7),它们使开关接通/断开；以及一对支点部(10),它们相对于操作输入部分别设置于按钮的中央部侧,在一对支点部中,与一对操作输入部中的通过操作输入使开关接通/断开的操作输入部相反的一侧的支点部成为按钮的摆动轴。(Provided is a rocker switch capable of easily setting an operation load to a design value without causing deterioration and increase in size of an external appearance and without being affected by an excessive reaction force. The rocker switch (1) is configured to have: a button (2) that swings when an operation input is made; a housing (3) that supports the button; a pair of switches (5) provided on both end sides of the center of the push button in the housing; a rubber contact (urging part) (6) for urging both ends of the push button toward the non-operation position; a pair of operation input units (7) for turning on/off the switch; and a pair of fulcrum portions (10) which are respectively arranged at the central portion side of the push button relative to the operation input portion, wherein one of the pair of fulcrum portions, which is opposite to the operation input portion that turns on/off the switch through the operation input, is used as a swinging shaft of the push button.)

1. A rocker switch, having:

a button that swings when operated;

a housing supporting the button;

a pair of switches provided at both end portions of the housing with respect to a central portion of the push button;

a biasing portion that biases both end portions of the button toward a non-operation position;

a pair of operation input units provided in the housing at positions corresponding to the pair of switches, respectively, for turning on/off the switches; and

a pair of fulcrum portions provided on a central portion side of the push button with respect to the pair of operation input portions, respectively,

among the pair of fulcrum portions, the fulcrum portion on the opposite side of the operation input portion, which turns on/off the switch by an operation input, among the pair of operation input portions becomes a swing axis of the button.

2. The rocker switch according to claim 1,

the fulcrum portion has a window hole and an engaging claw engageable with the window hole,

when an operation is input, a 1 st portion of the engagement claw on the opposite side of the biasing direction of the biasing portion and a 2 nd portion of the window hole facing the 1 st portion come into contact with each other to serve as the swing shaft.

3. The rocker switch according to claim 2,

the window hole is formed to be long in a swing direction of the button.

4. The rocker switch according to claim 3,

the window hole is formed in one of the button and the housing, and the engaging claw is formed in the other,

the button is swingably assembled to the housing by engagement of the window hole with the engaging claw and an engaging portion formed in a substantially central portion of the button in an opposing portion of the button and the housing that opposes a portion where the window hole and the engaging claw are provided.

5. The rocker switch according to any one of claims 1 to 4,

an erroneous operation preventing portion that restricts the parallel movement of the push button in the operation direction when both end portions of the push button are simultaneously operated or when the center portion of the push button is operated is provided on at least one of the push button and the housing.

6. The rocker switch according to claim 5,

the misoperation prevention part is provided with a stop piece which is arranged on at least one of the button and the shell in a protruding way,

a gap is formed between the stopper and the button or the housing, and the gap allows the button to swing and prevents the button from moving parallel to the operation direction by a predetermined amount or more.

Technical Field

The present invention relates to a rocker switch in which a pair of switches are selectively turned on and off by alternately pressing both end portions of a push button and swinging the push button.

Background

The rocker switch is configured to include: a push button that swings around a fulcrum when both end portions in a specific direction are selectively pressed; a housing that supports the button so as to be swingable; a pair of switches provided in the housing at positions corresponding to both end portions of the button, respectively; and a biasing unit that biases both end portions of the push button in directions opposite to the pressing operation. In such a rocker switch, when one of both end portions of a push button is pushed and the push button is swung about a fulcrum portion, one of a pair of switches is turned on. Therefore, when both end portions of the push button are alternately pressed, the pair of switches are alternately turned on/off.

However, as described above, when one of the two end portions of the push button of the rocker switch is pushed and the push button is swung around the fulcrum portion, the end portion on the opposite side to the pushing operation of the push button protrudes from the reference surface, which causes a problem that the appearance of the rocker switch is deteriorated.

Therefore, patent document 1 proposes a rocker switch in which: pins are provided at positions corresponding to both end portions of the push button on either one of the push button (push button) and the housing (support member), and long holes are provided at positions corresponding to the pins, so that the push button and the housing are engaged with each other in the long holes. According to such a rocker switch, when any one of the two end portions of the push button is pushed, the push button swings about a pin on the opposite side (the opposite side to the pushing operation) as a fulcrum, so that the end portion of the push button on the opposite side to the pushing operation does not protrude largely from the reference surface, and the appearance of the rocker switch is not impaired.

In addition, patent document 2 proposes a rocker switch in which: fulcrum portions are provided at portions extending from both end portions of the push button (push button) so as to be in contact with the back surface of the panel member (escutcheon), and action portions (pressing ribs) acting on the pair of switches are provided inside the fulcrum portions. According to such a rocker switch, when one of the two end portions of the push button is pushed to swing the push button, the push button swings inward of the panel member about a fulcrum portion provided at the other end portion of the push button, and therefore the other end portion of the push button (the end portion on the opposite side to the pushing operation) does not protrude largely from the panel member, and the appearance of the rocker switch is not impaired.

Patent document 1: japanese patent laid-open publication No. 2006-0040614

Patent document 2: japanese Kokai publication Sho 62-152329

However, in the rocker switch proposed in patent document 1, when the button is swung, the action portion of the button presses the switch (operation element) at a portion inside the fulcrum portion (pin), and therefore, when one of the two end portions of the button is pressed and the button is swung with the pin on the other end side (the opposite side to the pressing operation) as a fulcrum, the action portion of the other end portion of the button abuts against the switch and presses the switch (operation element), and therefore, the button receives a reaction force from the switch (operation element) on the opposite side to the pressing operation by the pressing, and there is a problem that it is difficult to set the operation load of the button to a predetermined design value due to the reaction force.

In the rocker switch proposed in patent document 2, the fulcrum portions are provided outside the both end portions of the push button, and therefore a predetermined gap needs to be secured between the fulcrum portions and the peripheral members, which causes a problem that the rocker switch is large in size.

Disclosure of Invention

The present invention has been made in view of the above problems, and an object of the present invention is to provide a rocker switch capable of easily setting an operation load to a design value without deteriorating and increasing the size of the appearance and without being affected by an excessive reaction force.

In order to achieve the above object, a rocker switch according to the present invention includes: a button that swings when operated; a housing supporting the button; a pair of switches provided at both end portions of the housing with respect to a central portion of the push button; a biasing portion that biases both end portions of the button toward a non-operation position; a pair of operation input units provided in the housing at positions corresponding to the pair of switches, respectively, for turning on/off the switches; and a pair of fulcrum portions provided at a central portion side of the push button with respect to the pair of operation input portions, respectively, wherein the fulcrum portion on an opposite side to the operation input portion that turns on/off the switch by an operation input among the pair of operation input portions serves as a swing axis of the push button.

According to the present invention, when, for example, one end portion of the push button is pressed to input an operation force to one operation input portion, the push button swings about the fulcrum portion on the side opposite to the operation input as the swing axis, so that the displacement amount (the amount of projection from the reference surface) of the push button on the side opposite to the operation input is suppressed to be small, and the rocker switch can be prevented from being deteriorated in appearance. Further, since the operation input portion and the fulcrum portion do not protrude outward from both end portions of the push button, the rocker switch can be prevented from being increased in size. Further, since the pair of operation input portions are disposed outside the pair of fulcrum portions, when the button is swung with the fulcrum portion on the side opposite to the operation input as the swing axis, the end portion on the side opposite to the operation input of the button is separated from the switch side, and therefore, a reaction force from the switch side is not received. Therefore, the operation load of the button can be easily set to the design value without being affected by the excessive reaction force.

Drawings

Fig. 1 is a front view of the rocker switch of the present invention.

Fig. 2 is a bottom view (in the direction of arrow 2 of fig. 1) of the rocker switch of the present invention.

Fig. 3 is a top view (view in the direction of arrow 3 of fig. 1) of the rocker switch of the present invention.

Fig. 4 is a cross-sectional view taken along line 4-4 of fig. 1.

Fig. 5 is an exploded perspective view showing the rocker switch of the present invention with a portion broken away.

Fig. 6 is a cross-sectional view for explaining the operation of the rocker switch according to the present invention, in which fig. 6 (a) and (b) are views showing a state in which one end of the push button is pushed, and fig. 6 (c) is a view showing a state in which the center of the push button is pushed.

Fig. 7 is a diagram schematically showing a relationship between a fulcrum and an operating point when a push button of a rocker switch is pressed and a reaction force acting on the push button from a switch (operating element), fig. 7 (a) is a diagram of the rocker switch according to the present invention, and fig. 7 (b) is a diagram of a conventional rocker switch.

Description of the reference symbols

1: a rocker switch; 2: a button; 2 a: a long hole of the button; 2 b: a window aperture of the button; 2b 1: site 2 of fenestration; 3: a housing; 3 a: a snap-fit projection of the housing; 3 b: a snap-in claw of the housing; 3b 1: the 1 st part of the clamping claw; 4: a circuit board; 5: a switch; 5 a: a press-in part; 6: a rubber contact (urging portion); 6A: a convex portion of the rubber contact; 7: an operation member (operation input unit); 8: a stopper (misoperation preventing portion); 9: a fastening part; 10: a fulcrum section; A. b: the distance between the left end and the right end of the button and the fulcrum; a: a fulcrum; f: a pressing force; s: a space; x1, x 2: displacement amounts of left and right end portions of the button; δ: a gap between the button and the stop; θ: the rocking angle of the button.

Detailed Description

Hereinafter, embodiments of the present invention will be described with reference to the drawings.

[ Structure of seesaw switch ]

Fig. 1 is a front view of a rocker switch according to the present invention, fig. 2 is a bottom view of the rocker switch (a view in the direction of arrow 2 of fig. 2), fig. 3 is a top view of the rocker switch (a view in the direction of arrow 3 of fig. 1), fig. 4 is a cross-sectional view taken along line 4-4 of fig. 1, and fig. 5 is an exploded perspective view showing the rocker switch partially cut away. In the following description, the lateral direction is referred to as "left and right" and the vertical direction is referred to as "up and down" as indicated by arrows in fig. 1, and the front side is referred to as "rear" and the rear side is referred to as "front" as indicated by arrows in fig. 2.

The illustrated rocker switch 1 is provided, for example, at a spoke portion of a not-illustrated steering wheel of a vehicle, and the driver can operate the rocker switch 1 while holding the steering wheel. The rocker switch 1 includes a rectangular box-shaped push button 2 elongated in the left-right direction (specific direction), and a rectangular box-shaped housing 3 elongated in the left-right direction and supporting the push button 2 to be swingable. Here, in the present embodiment, the push button 2 and the housing 3 are each molded from a resin such as ABS, and the push button 2 is disposed on the front side (rear side) and the housing 3 is disposed on the rear side (front side).

As shown in fig. 3, a plate-shaped bracket 2A is horizontally projected forward (toward the housing 3) from the center in the left-right direction of the upper surface of the push button 2, and a long hole 2A that is long in the front-rear direction is formed at the front end portion of the bracket 2A. A cylindrical engaging projection 3a is integrally provided in the upper surface of the housing 3 so as to project upward from the center in the left-right direction, and the engaging projection 3a engages with a long hole 2A of a bracket 2A provided in the upper surface of the push button 2. Here, the elongated hole 2a and the engaging projection 3a constitute an engaging portion 9 of the push button 2 and the housing 3.

As shown in fig. 2, 4, and 5, rectangular window holes (engagement holes) 2b that are long in the swing direction of the push button 2 are formed in the lower surface of the push button 2 at two left and right positions near the center in the left-right direction. Engaging claws 3b are integrally provided in two left and right portions of the lower surface of the housing 3 (portions corresponding to the two window holes 2b of the push button 2) in a protruding manner, and these engaging claws 3b are engaged with the two window holes 2b formed in the lower surface of the push button 2. Therefore, the push button 2 is swingably assembled to the housing 3 by engaging the engaging projection 3a provided on the upper surface of the housing 3 with the elongated hole 2A of the bracket 2A provided on the upper surface of the push button 2, and engaging the two engaging claws 3b provided on the lower surface of the housing 3 with the two window holes 2b formed on the lower surface of the push button 2. As will be described later, the two window holes 2b of the push button 2 and the two engaging claws 3b of the housing 3, which are engaged with each other, constitute fulcrum portions 10 as fulcrums when the push button 2 swings, and the two fulcrum portions 10 alternately serve as swing axes of the push button 2 every time the swing direction of the push button 2 changes. In this way, in the present embodiment, the window hole 2b and the engaging claw 3b for assembling the push button 2 to the housing 3 constitute the fulcrum portion 10 as the swing shaft of the push button 2.

Here, as shown in fig. 2, the left and right fulcrum portions 10 are each composed of a window hole 2b and an engaging claw 3b engageable with the window hole 2b, but when one of the left and right ends of the push button 2 is pressed, the 1 st portion 3b1 on the opposite side to the biasing direction of the rubber contact 6 in the engaging claw 3b and the 2 nd portion 2b1 facing the 1 st portion 3b1 in the window hole 2b abut against each other, and a swing shaft as a swing center of the push button 2 is formed.

As described above, when the push buttons 2 are assembled to the housing 3, as shown in fig. 4, a space S is formed between these push buttons 2 and the housing 3, and the flat plate-like circuit board 4 is provided on the rear surface of the housing 3 facing the space S. Switches (micro switches in the present embodiment) 5 that are turned on/off by a pressing operation are attached to both left and right ends of the circuit board 4 (two portions corresponding to both left and right ends of the push button 2).

As shown in fig. 4, a rubber contact 6 covering the circuit board 4 and the two switches 5 is provided in a space S formed by the push button 2 and the housing 3, and a convex portion 6A protruding rearward (upward in fig. 4) is integrally formed at both end portions of the rubber contact 6 covering the left and right switches 5.

Here, when the rocker switch 1 is in a non-operating state (initial position) (when the push button 2 is not pushed), as shown in fig. 4, the protruding portions 6A of the rubber contacts 6 covering the two switches 5 do not contact the left and right switches 5, and a predetermined gap is formed between the two switches. The operating element 7 is interposed between the left and right convex portions 6A of the rubber contact 6 and the left and right end portions of the push button 2. Here, the left and right operation members 7 constitute an operation input section for transmitting a pressing operation force to the left and right switches 5 to turn on/off the switches 5. Therefore, the left and right convex portions 6A of the rubber contact 6 constitute biasing portions that bias the left and right end portions of the push button 2 in opposite directions (upward in fig. 4) to the operation input via the left and right operation pieces 7. In the present embodiment, the rubber contact 6 separate from the switch 5 is used as the biasing portion that biases the both end portions of the push button 2 toward the non-operation position, but an elastic member such as a spring, not shown, built in the switch 5, or an elastic member provided separately from the switch 5 may be used as the biasing portion.

As shown in fig. 4, a rod-shaped stopper 8 is vertically provided on the center portion of the housing 3 side (the rubber contact 6 in the present embodiment) in the left-right direction toward the push button 2, and the stopper 8 constitutes an erroneous operation preventing portion for preventing an erroneous operation of the rocker switch 1. The stopper 8 restricts the push button 2 from moving parallel to the pushing direction when both end portions of the push button 2 are simultaneously pushed or when the center portion in the left-right direction between both end portions of the push button 2 is pushed. Here, a gap δ that allows the push button 2 to swing and prevents the push button 2 from moving parallel in the pressing direction (downward in fig. 4) by a predetermined amount or more is formed between the stopper 8 and the push button 2.

However, in the rocker switch 1 of the present embodiment, as shown in fig. 4, the operating elements 7 as operation input portions for turning on and off the left and right switches 5 are provided at positions corresponding to both ends in the left-right direction of the push button 2, respectively, and the fulcrum portions 10 are provided at two positions on the inner side in the left-right direction of the operating elements 7, and the fulcrum portions 10 alternately serve as swing axes (fulcrums) by swinging caused by pressing operation of the push button 2. Here, as described above, the pivot shaft of the fulcrum portion 10 is constituted by the 2 nd portion 2b1 of the window hole 2b formed at both left and right positions on the lower surface of the push button 2 and the 1 st portion 3b1 of the engaging pawl 3b provided at both left and right positions protruding on the lower surface of the housing 3. In the present embodiment, the operating elements 7 as operation input portions are provided at positions corresponding to both left and right end portions of the push button 2, and the switches 5 are turned on and off by transmitting a pressing operation force applied to one of both end portions of the push button 2 to the left and right switches 5 via the operating elements 7, respectively, but the press-in portions 5a of the switches 5 may be extended to be directly below the push button 2, and the press-in portions 5a may be configured as operation input portions.

In the state shown in fig. 4 in which the rocker switch 1 is in the non-operating state (initial position), the push button 2 is biased in the opposite direction to the pressing operation (upward in fig. 4) by the left and right protrusions 6A of the rubber contact 6 serving as the biasing portion via the left and right operation pieces 7, and therefore the left and right window holes 2b of the push button 2 constituting the fulcrum portion are in contact with the left and right engagement claws 3b of the housing 3. In this state, the left and right switches 5 are both in the off state.

[ Effect of seesaw switch ]

Next, the operation of the rocker switch 1 configured as described above will be described below with reference to fig. 6 and 7.

Fig. 6 is a schematic diagram for explaining the operation of the rocker switch according to the present invention, in which fig. 6 (a) and (b) are respectively a diagram showing a state in which one end of a button is pressed, fig. 6 (c) is a diagram showing a state in which the center of the button is pressed, fig. 7 is a diagram schematically showing a relationship between a fulcrum and an operating point when the button of the rocker switch is pressed and a reaction force acting on the button from a switch (operating element), fig. 7 (a) is a diagram relating to the rocker switch according to the present invention, and fig. 7 (b) is a diagram relating to a conventional rocker switch.

When the left end portion of the push button 2 is pushed from the state shown in fig. 4 in which the rocker switch 1 is in the non-operating state (initial position), the push button 2 swings with a point a of the fulcrum portion 10 on the opposite side (right side of fig. 6 a) to the pushing operation as a fulcrum, as shown in fig. 6 a. In addition, the oscillation of the push button 2 is not hindered by the stopper 8.

Then, the switch 5 on the pressing operation side (left side) is pressed by the operating element 7 and the convex portion 6A of the rubber contact 6 to be turned on, and the switch 5 on the opposite side (right side) to the pressing operation is maintained in the off state.

Here, the swing of the push button 2 is schematically shown in fig. 7 (a), and since the left end portion of the push button 2 is pressed, the push button 2 swings from the position of the dashed line to the position of the solid line around the fulcrum a, and when the switch 5 on one side (left side) is turned on, the left end portion of the push button 2 is displaced by x1 shown in the drawing, and the right end portion (end portion on the opposite side to the pressing operation) is displaced by x2 shown in the drawing. Assuming that the swing angle of the push button 2 at this time is θ, the distance from the left end of the push button 2 to the fulcrum a is a, and the distance from the right end of the push button 2 to the fulcrum a is B, the displacement x1 of the left end of the push button 2 and the displacement x2 of the right end are obtained by the following equations, respectively.

x1＝A·sinθ…(1)

x2＝B·sinθ…(2)

Here, since a > B, the following magnitude relationship holds between the displacements x1 and x 2.

x1＞x2…(3)

Thus, the displacement x2 of the end portion (right end portion) on the side opposite to the pressing operation of the push button 2 is suppressed to be small, and therefore the amount of projection of the end portion (right end portion) is suppressed to be small, thereby preventing the appearance of the rocker switch 1 from deteriorating.

In the rocker switch 1 of the present embodiment, since the operating element 7, which is the left and right operation input portions of the push button 2, is disposed outside the fulcrum portion 10 (point a) in the left-right direction, the entire pressing force F acts on the switch 5 via the operating element 7 at the end portion (left end portion) on the pressing operation side of the push button 2, whereas the end portion (right end portion) on the opposite side to the pressing operation of the push button 2 is displaced in a direction away from the operating element 7 without pressing the operating element 7. Therefore, the right end portion of the push button 2 does not receive a reaction force from the operation element 7, and all of the pressing forces F acting on the left end portion of the push button 2 act on one (left) switch 5 as described above. Therefore, the operation load of the push button 2 can be easily set to the design value without being affected by the excessive reaction force.

In contrast, in the conventional rocker switch, fig. 7 (b) schematically shows the relationship between the fulcrum and the operating point and the reaction force acting on the push button from the switch (operating element).

That is, when the left end portion of the push button 102 is pushed, for example, the pushing force F1 acts on the left-side operation element 107 of the push button 102, and the operation element 107 is pushed, and at this time, the push button 102 receives the reaction force R1 shown in the drawing from the operation element 107. Here, in the conventional rocker switch, since the operating element 107 is disposed inside the fulcrum a ', when the push button 102 swings from the position indicated by the dashed line to the position indicated by the solid line around the fulcrum a' on the right side in the drawing, the right end portion of fig. 7 (b) of the push button 102 abuts against the operating element 107 and presses the operating element 107 with the pressing force F2, and therefore the push button 102 receives the reaction force R2 indicated in the drawing from the operating element 107 on the right side. In this way, in the conventional rocker switch, since the push button 102 receives the reaction forces R1 and R2 from the left and right operating elements 107, respectively, it is difficult to set the operating load of the push button 102 to the design value, and setting the operating load requires a large amount of labor.

However, in the rocker switch 1 of the present embodiment, all the components such as the fulcrum portion (the window hole 2b of the button 2 and the engagement claw 3b of the housing 3) 10, the operation element 7, and the switch 5 are arranged within the range of the length of the button 2 in the left-right direction, and therefore, the rocker switch 1 can be prevented from being enlarged.

Fig. 6 (b) shows a state in which the right end portion of the push button 2 is pushed, and at this time, the push button 2 swings about a fulcrum a on the opposite side (left side) to the pushing operation, and the right switch 5 is pushed via the operating element 7 and the convex portion 6A of the rubber contact 6, thereby turning on the switch 5. At this time, the switch 5 on the opposite side (left side) is maintained in the off state. In addition, the stopper 8 does not hinder the swing of the push button 2.

When the right end portion of the push button 2 is pushed, the push button 2 is also rotated about the fulcrum a on the side opposite to the pushing operation (left side of fig. 6 (b)), and the amount of displacement of the end portion (left end portion) on the side opposite to the pushing operation of the push button 2 at this time is suppressed to be small, so that the appearance of the rocker switch 1 is not impaired. For the same reason as described above, the left end portion of the push button 2 does not receive a reaction force from the operation element 7, and all of the pressing forces F acting on the right end portion of the push button 2 act on the right switch 5. Therefore, the operation load of the push button 2 can be easily set to the design value without being affected by the excessive reaction force.

Next, fig. 6 (c) shows a state in which the center portion in the left-right direction of the push button 2 is pressed, and at this time, the push button 2 is moved in parallel forward (downward in fig. 6 (c)) by a pressing force F acting on the center portion. Here, the parallel movement amount of the push button 2 is limited to a predetermined amount (a gap δ between the push button 2 and the stopper 8) by the push button 2 abutting against the front end of the stopper 8. Here, the gap δ between the push button 2 and the stopper 8 is set to a value at which the left and right switches 5 are not turned on. Therefore, when the center portion in the lateral direction of the push button 2 is pressed, it is possible to reliably prevent the occurrence of a malfunction in which the left and right switches 5 are simultaneously turned on.

Although not shown, even when both left and right ends of the push button 2 are simultaneously pressed, the stopper 8 prevents the push button 2 from moving parallel by a predetermined amount (the gap δ between the push button 2 and the stopper 8) or more, and therefore, it is possible to reliably prevent the occurrence of malfunction in which the left and right switches 5 are simultaneously turned on.

As is clear from the above description, according to the present invention, the following effects can be obtained: the operation load of the push button 2 can be easily set to the design value without causing deterioration and increase in size of the appearance of the rocker switch 1 and without being affected by an excessive reaction force.

In the above embodiment, the window hole 2b constituting the fulcrum portion 10 is formed in the push button 2, and the engaging claw 3b is provided to protrude from the housing 3, but on the contrary, an elongated hole may be formed in the housing 3, and the engaging claw may be provided to protrude from the push button 2.

In the above embodiment, the stopper 8 is provided on the housing 3 side, but the stopper 8 may be provided on the push button 2 side.

In the illustrated embodiment, the operation mode of the push button 2 is a pressing operation, but a rod-like member may be provided so as to protrude from the push button 2, and the push button 2 may be swung by tilting the rod-like member.

The present invention is not limited to the embodiments described above, and various modifications can be made within the scope of the technical idea described in the claims, the description, and the drawings.

Industrial applicability

The present invention can be applied not only to a rocker switch disposed on a spoke portion of a steering wheel of a vehicle, but also to all other rocker switches.