The present invention relates to a switch device that regulates movement of an operation member.
In recent years, push-button-type switch devices have been used to start and stop automobile engines. A switch device includes a housing member in which an operation member is accommodated, and a driver pushes the operation member to start or stop the engine. When the driver releases his/her finger from the operation member, the pushing force acting on the operation member is released, and a restoring force is applied to the operation member to return the operation member to the original position.
As a related technique, a push button switch has been proposed, in which a flexible protrusion is integrally formed on the surface of a plunger which faces a base stopper, and a flexible means is provided to bend the flexible protrusion while the plunger is pushed (see Japanese Laid-open Utility Model Publication (Kokai) No. S63-118129). Also, a silencer structure for a push button switch has been proposed, in which an elastic piece is integrally provided on a slider and an abutting portion is integrally provided on a casing. The elastic piece abuts on the abutting portion and bends (see Japanese Laid-open Utility Model Publication (Kokai) No. S51-93969).
Usually, the switch device includes an urging member having elasticity, and when the pushing force to the operation member is released from the switch device, the operation member returns to its original position by an urging force of the urging member. If a regulating member is provided for stopping the operation member at a predetermined position during the return of the operation member to the original position, the operation member receives the urging force and vigorously comes into contact with the regulating member. At this time, a large impact sound is generated if a large contact area is provided between the operation member and the regulating member.
The push button switches described in Japanese Laid-open Utility Model Publications (Kokai) No. S63-118129 and No. S51-93969 are the switches that mute sound generated when the switch is pushed. These switches do not mute the impact sound generated when the operation member returns to the original position after the pushing force of the switch device on the operation member is released. For example, the technique of Japanese Laid-open Utility Model Publication (Kokai) No. S63-118129 applies an urging force by a return spring in a direction opposite to the pushing direction when the plunger main body returns to the original position. At this time, a larger impact sound is generated when the plunger main body returns to the original position.
Similarly, with the technique disclosed in Japanese Laid-open Utility Model Publication (Kokai) No. S51-93969, a larger impact sound is generated when the slider returns to the original position by the urging force of the coil spring. When the switch is operated, the operation member is pushed in against an elastic force of, for example, the return spring or the coil spring. Therefore, it is expected that a larger impact sound is generated when the operation member returns to the original position compared with the impact sound generated when the switch is operated.
The present invention provides a switch device that reduces an impact sound generated when an operation member returns to its original position.
Accordingly, an aspect of the present invention provides a switch device including a housing member, an operation member accommodated in the housing member and capable of being pushed, and an urging member that urges the operation member in a direction opposite to a pushing direction, in which the housing member includes a regulating portion that regulates movement of the operation member in the opposite direction, the operation member includes a portion to be regulated that abuts on the regulating portion, and when the movement of the operation member in the opposite direction is regulated, the regulating portion and the portion to be regulated make a line contact with each other first.
According to the present invention, the impact sound generated when the operation member of the switch device returns to its original position can be reduced.
Further features of the present invention will become apparent from the following description of exemplary embodiments (with reference to the attached drawings).
Hereinafter, an embodiment will be described with reference to the accompanying drawings. It should be noted that the scope of the present invention is not limited to the configurations described in the following embodiment. Hereinafter, the switch device is described as a switch for starting and stopping an automobile engine. However, the switch device to which the present embodiment is applied is not limited to the switch for starting and stopping an automobile engine.
The housing member 2 in
Of two prongs of the two-pronged stopper 5A, 5B, a slope S1 is formed on the prong 5A at a portion abutting on the tab 6. Of the two prongs of the two-pronged stopper 5A, 5B, a slope S2 is formed on the prong 5B at a portion abutting on the tab 6. The slopes S1 and S2 are examples of a first slope. On the other hand, slopes S3 and S4 are formed on the tab 6 at portions abutting on the two prongs of the two-pronged stopper 5A, 5B. The slopes S3 and S4 are examples of a second slope. The slopes S1 and S2 are slopes that expand symmetrically in a direction in which the operation knob 3 is pushed, and when assuming the direction in which the operation knob 3 is pushed as a standard direction, are tilted at the same angle regarding the standard direction. The slopes S3 and S4 formed on the tab 6 narrow symmetrically in a direction opposite to the standard direction, and are tilted at the same angle regarding the standard direction. In the present embodiment, the tilt angle of the slopes S1 and S2 is different from the tilt angle of the slopes S3 and S4 regarding the standard direction. Therefore, when the movement of the operation knob 3 is regulated, the two-pronged stopper 5A, 5B and the tab 6 make a line contact first. In the example of
As described above, when the pushing force on the operation knob 3 is released, the operation knob 3 is accelerated by the urging force of the spring 7. The tab 6 formed on the accelerated operation knob 3 abuts on the two-pronged stopper 5A, 5B. If the movement of the operation knob 3 is regulated by a surface contact between the operation knob 3 and the housing member 2, and when the operation knob 3 make a surface contact vigorously with the housing member 2, the surfaces collide with each other and a large impact sound is generated. On the other hand, the present embodiment regulates the movement of the operation knob 3 by the two-pronged stopper 5A, 5B by making the line contact with the tab 6 first. Even when the tab 6 vigorously comes into contact with the two-pronged stopper 5A, 5B, the generated impact sound can be reduced compared to a case where the movement of the operation knob 3 is regulated by the surface contact.
Further, the two-pronged stopper 5A, 5B and the tab 6 make the line contact with each other at the slopes formed on the two-pronged stopper 5A, 5B and the slopes formed on the tab 6. Since the two-pronged stopper 5A, 5B and the tab 6, which make the line contact, are slopes, the force acting on the line contact portions can be alleviated when the movement of the operation knob 3 is regulated. For example, if the portions of the two-pronged stopper 5A, 5B that make the line contact with the tab 6 are at right angle, these portions of the two-pronged stopper 5A, 5B receive a large force when the portions make the line contact with the tab 6. This increases damage of the portions where the two-pronged stopper 5A, 5B make the line contact with the tab 6 and causes scratching or wearing at the line contact portions. In contrast, the present embodiment can reduce the damage, because the first and second slopes are both slopes, so that the force acting on the line contact portions can be alleviated.
In the present embodiment, the tilt angles of the slopes S1 and S2 formed on the two-pronged stopper 5A, 5B are gentler than the tilt angles of the slopes S3 and S4 formed on the tab 6. Angles of the slopes S1 and S2 with respect to the direction in which the operation knob 3 is pushed (tilt angles of the slopes S1 and S2) are larger than the angles of the slopes S3 and S4 with respect to the direction in which the operation knob 3 is pushed (tilt angles of the slopes S3, S4). If the tilt angles of the slopes S1, S2 formed on the two-pronged stopper 5A, 5B are steep, the damage of the line contact portions of the two-pronged stopper 5A, 5B increases when the two-pronged stopper 5A, 5B receives the tab 6. The present embodiment can reduce the damage because the tilt angles of the slopes S1, S2 formed on the two-pronged stopper 5A, 5B are gentler than the tilt angles of the slopes S3, S4 formed on the tab 6.
As described above, the movement of the operation knob 3 is regulated when the tab 6 abuts on the two-pronged stopper 5A, 5B which serves as the receiving portion. In the present embodiment, the two-pronged stopper 5A, 5B has a higher flexibility than the tab 6. When the movement of the operation knob 3 is regulated, the tab 6 abuts on the two-pronged stopper 5A, 5B. At this time, as shown in
The two-pronged stopper 5A, 5B bends by the tab 6 when the movement of the operation knob 3 is regulated, thus absorbing the impact of abutting when the tab 6 abuts on the two-pronged stopper 5A, 5B. Therefore, it is possible to further reduce the impact sound when the tab 6 abuts on the two-pronged stopper 5A, 5B. It should be noted that the flexibility of the two-pronged stopper 5A, 5B is preferably higher than that of the tab 6, but may be substantially equal to or lower than the flexibility of the tab 6. In this case, the two-pronged stopper 5A, 5B which is made of resin also bends to some extent when abutting on the tab 6, so that the impact sound may be reduced to some extent.
As described above, the tilt angles of the slopes S1 and S2 formed on the two-pronged stopper 5A, 5B are gentler than the tilt angles of the slopes S3 and S4 formed on the tab 6. In other words, the tilt angles of the slopes S3 and S4 formed on the tab 6 are steeper than the tilt angles of the slopes S1 and S2 formed on the two-pronged stopper 5A, 5B. Therefore, the tab 6 having the slopes both having a steep tilt angle and a low flexibility abuts on the two-pronged stopper 5A, 5B having the slopes of a gentle tilt angle and a high flexibility. As a result, the tab 6 can largely bend the two-pronged stopper 5A, 5B and reduce the impact sound.
As described above, when the tab 6 abuts on the two-pronged stopper 5A, 5B, both prongs of the two-pronged stopper 5A, 5B bend. The two-pronged stopper 5A, 5B bends instantaneously, and then immediately return to the original state (unbent state). As a result, the two-pronged stopper 5A, 5B can immediately regain its original function as the regulating portion.
As described above, when the operation knob 3 returns to the original position by the urging force of the spring 7, the movement of the operation knob 3 is regulated by the two-pronged stopper 5A, 5B that makes the line contact with the tab 6 first. This allows reduction of the impact sound generated when the movement of the operation knob 3 is regulated.
In the example described above, the slopes are formed on both prongs of the two-pronged stopper 5A, 5B and the tab 6, but the slopes may not be formed on either one of the two prongs of the two-pronged stopper 5A, 5B and the tab 6. For example,
Meanwhile, the two-pronged stopper 5A, 5B may not be formed on the housing member 2. For example,
This application claims the benefit of Japanese Patent Application No. 2019-041775 filed on Mar. 7, 2019 which is hereby incorporated by reference herein in its entirety.
Number | Date | Country | Kind |
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JP2019-041775 | Mar 2019 | JP | national |
Number | Name | Date | Kind |
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4851625 | Liebich | Jul 1989 | A |
6333479 | Tai | Dec 2001 | B1 |
Number | Date | Country |
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S51-093969 | Jul 1976 | JP |
S63-118129 | Jul 1988 | JP |
S63-118129 | Jul 1998 | JP |
Number | Date | Country | |
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20200286697 A1 | Sep 2020 | US |