KR100322778B1 - Push switch - Google Patents

Abstract

Conventional products tend to generate bounce on the stationary contactor or the support terminals when the movable contactor is switched from OFF to ON, and is burned out by arc heat, resulting in reliability and product life. There was a problem of being damaged.

Between the slider 5 and the movable contact 4, a compression coil spring 6 for applying a force in a direction opposite to the pressing direction of the slider 5 is provided, and the slider 5 is operated during its reciprocating motion. In accordance with the driven portion 4b of the contactor 4, the driving portions 5b and 5c for forcibly tilting the movable contactor 4 are provided. Further, an offset positional relationship in which the compression coil spring 6 is always pushed in at an angle to the connecting end 4d of the movable contact 4 is adopted, so that one side of the point 4c of the movable contact 4 is supported by the support terminal ( Resilient contact was always made with one concave wall surface of 2).

Description

Push switch {PUSH SWITCH}

The present invention relates to a push switch suitable for use as a power switch or the like.

As a push switch used in a power switch or the like, a fast-moving reversal mechanism that normally performs on / off contact switching when a push operation is performed is employed.

As such a push switch, as previously described, for example, in Japanese Patent Application Laid-Open No. 60-33543, it has a top cover, a case in which a support terminal and a fixed contactor are provided at the bottom of the inside, and the support A movable contact supported by the terminal so as to be inclined and detachable from the fixed contactor, a compression coil spring which always provides elastic force to the movable contactor, and a compression coil spring inserted into the case so as to be reciprocated so that the compression coil spring is laterally The structure is provided with the slider (operator) attached so that it may protrude to the (movable contact side), and the return spring which presses this slider in the opposite direction to a pushing operation direction. In the conventional push switch, when the slider is pushed in the off state, the compression coil spring driven by the slider is compressed to push one end of the movable contact, but when this one exceeds the dead point, the movable contact is inclined vigorously. Since the fixed contactor is in contact with the fixed contactor, the fixed contactor and the support terminal are switched on by the movable contactor. When the slider is unlocked in the on state, the slider moving in the opposite direction to the pressing operation direction due to the spring force of the return spring drives the compression coil spring, so that one end of the movable contact that is subjected to the spring force from the compression coil spring. At the moment when the additional dead center is exceeded, the movable contact is inclined vigorously in the direction away from the fixed contact to be switched off.

The above-described conventional push switch has a resilience force of the compression coil spring when performing the operation of contacting the movable contactor with the fixed contact while the coil spring which has increased the compression amount is momentarily elongated when switched from off to on. The contact of both contacts in this weakening process caused the spring to bounce immediately after the movable contact touched the fixed contact. In addition, since both contacts contact each other in the process of weakening the elasticity of the compression coil spring, bounce occurs well in the point part mounted on the support terminal among the movable contacts. When such a bounce occurs, high temperature arcs are easily generated between the movable contactor and the stationary contactor, or between the movable contactor and the support terminal, so that both the contactor and the support terminal are burned out by the arc heat, resulting in reliability and product life. Has a great adverse effect on.

Means to solve the problem

The present invention allows the elasticity of the spring member provided between the movable contactor and the slider to be rapidly increased when the movable contactor contacts the stationary contactor. With this configuration, the bounce of the movable contact, which was concerned when switching from off to on, can be greatly reduced, thereby improving reliability and lifespan.

1 is an exploded perspective view of a push switch according to an embodiment of the present invention.

Fig. 2 is an operation explanatory diagram showing a switch off state in the embodiment.

3 is an operation explanatory diagram showing a state during on-off switching in the embodiment;

4 is an operation explanatory diagram showing a switch-on state in the embodiment;

Fig. 5 is a sectional view showing an offset positional relationship between a movable contact and a compression coil spring in the embodiment.

* Description of the symbols for the main parts of the drawings *

1 case 2 support terminal

2a: recessed bottom surface 2b: recessed wall surface

3: fixed contact 4: movable contact

4a: contact part 4b: driven part

4c: branch 5: slider

5b, 5c: drive portion 6: compression coil spring

7: hanging pin 8: metal frame

The push switch of the present invention is provided with a support terminal for supporting the movable contact in an inclined portion at the bottom of the case, and a fixed contact with which the movable contact is detachable, and at the same time by tilting the movable contact on and off. A push switch in which a slider for performing contact switching of the switch is reciprocally inserted into the case, and a spring member is provided between the slider and the movable contact to apply a force in a direction opposite to the pushing direction. The slider is provided with a driving portion for forcibly tilting the movable contactor in engagement with a part of the movable contactor during the reciprocating motion.

The push switch configured as described above, when the switch is operated from the off state to the on state by pushing the slider, the driving portion of the slider is inclined to be inclined to move the movable contactor, and the movable contactor exceeds the dead point. The movable contact can be pushed back through the spring member by the slider receiving the inertial force of the pressing operation when the tilting motion is strongly directed toward the fixed contact. For this reason, when the movable contactor contacts the stationary contactor, the elasticity of the spring member can be quickly increased, and the movable contactor can greatly reduce the bounce occurring on the stationary contactor. In addition, the spring member not only imparts elasticity to the movable contact, but also serves as a return spring for automatically returning the pushed slider to the initial position, thereby reducing the number of parts.

In addition to this configuration, by setting the direction of the elastic force applied by the spring member to the movable contactor in a non-parallel direction with respect to the rotational movement surface of the movable contactor, the portion mounted on the support terminal of the movable contactor ( If one side of the point portion is configured to always make elastic contact with the support terminal wall, the bounce generated by the movable contact on the support terminal can be greatly reduced.

Example

1 to 5, an embodiment of the push switch according to the present invention will be described. As shown in the exploded perspective view of FIG. 3) is also provided with a case 1, also called a conductor plate, mounted on the bottom surface 2a of the recess of the support terminal 2 and supported inclinedly, and at the same time the contact portion 4a with respect to the fixed contactor 3; 6) a slider (5) provided with a movable contactor (4) which can be detached from and detached from the case (1) by an operator for tilting the movable contactor (4) to perform on / off contact switching. A compression coil spring 6 provided between the slider 5 and the movable contact 4 and forcing the slider 5 in the opposite direction to the pressing operation direction, and the heart-shaped groove 5a of the slider 5; Hanging on to the case (1) The garter of the slider 5 protruding from the case 1 while being caulked and fixed to the case 1 by the pin 7 and the attachment plate for attaching this push switch to an external device is provided as a guide piece 8a. It is comprised by the metal frame 8 to regulate.

In addition, as shown in the operation explanatory drawing of FIGS. 2-4, the front end part of the slider 5 engages with the driven part 4b provided in the one end part of the movable contact part 4 at the time of the reciprocation movement, and this movable contact part 4 is carried out. Drive portions 5b, 5c for forcibly tilting) are provided. And as shown in sectional drawing FIG. 5 seen from the direction different from 90 degree | times from FIGS. ) Is set in a direction non-parallel with respect to the rotational plane of rotation. That is, the inclined motion of the movable contact 4 is parallel to the plane extending in the left and right direction in FIG. 5 and orthogonal to the ground, but the compression coil spring 6 is slightly inclined downward in the direction shown in this plane. Is applied to the movable contactor 4, and therefore, one side of the narrow point portion 4c mounted on the recess bottom surface 2a of the support terminal 2 among the movable contactor 4 is It is always in elastic contact with the one side concave wall surface 2b of this support terminal 2. Moreover, the heart cam mechanism is comprised by the groove | channel 5a of the slider 5, and the hooking pin 7, When an operator pushes the slider 5 by predetermined stroke and switches it on, this slider 5 is carried out in the on state. Is locked, and when the slider 5 is pushed in again, the lock is released to switch to the off state.

Next, the operation of the above-described push switch will be described.

When the slider 5 is pushed to the left shown in the off state shown in Fig. 2, the connecting end 4d of the movable contact 4 is compressed while the compression coil spring 6 pushed into the slider 5 is compressed. 3, since the driving portion 5b of the slider 5 is engaged with the driven portion 4b of the movable contact 4 to forcibly tilt the movable contact 4 in the clockwise direction shown, FIG. At the moment when the connecting end 4d exceeds the dead point as shown in FIG. 4, the movable contactor 4 is inclined vigorously so that the contact portion 4a abuts against the fixed contactor 3, and the movable contactor is shown in FIG. 4. Through 4, the fixed contact 3 and the support terminal 2 are switched on. However, when the connecting end portion 4d exceeds the dead point and the contact portion 4a is vigorously directed toward the fixed contactor 3, the slider 5, which is subjected to the inertia force of the pressing operation, is moved through the compression coil spring 6 to the movable contactor ( Since 4) is pushed in the rear, when the contact portion 4a abuts on the fixed contactor 3, the compression coil spring 6 pushed into the slider 5 in the rear is rapidly compressed. As a result, when the contact portion 4a of the movable contactor 4 contacts the stationary contactor 3, the elastic force received by the movable contactor 4 from the compression coil spring 6 quickly increases, so that the contact portion ( There is no fear that 4a) will cause a large bounce on the stationary contact 3. In this way, when the push switch is switched to the on state, the slider 5 is locked to the heart cam mechanism in the position shown in FIG.

When the slider 5 is pushed in the on state again, the lock of the slider 5 by the heart cam mechanism is released, so that the slider 5 is moved from the compression operation direction due to the elastic force of the compression coil spring 6. Go in the reverse direction. Then, the driving portion 5c of the slider 5 is engaged with the driven portion 4b of the movable contact 4 to force the movable contact 4 to incline, so that the contact portion 4a is fixed to the fixed contact 3. Immediately after disengagement from and off, the connecting end portion 4d crosses the dead point, and the movable contactor 4 inclines vigorously to return to the state of FIG. 2.

When assembling the above-described push switch, the compression coil spring 6 is knitted on the slider 5 in advance, while the support terminal 2 and the fixed contact 3 are press-fitted in the case 1, and the movable contact 4 ), The slider 5 is pushed to the two ends of the support terminal 2 by pressing the side closer to the bent portion 4e than the point portion 4c of the movable contact 4. Since the movable contactor 4 moves parallel to the stationary contactor 3 in the pushing direction when it is inserted into (1), the narrow point portion 4c is moved into the recess 2c of the support terminal 2. In addition, the driven portion 4b can be easily inserted into the driving portions 5b and 5c of the slider 5.

As described above, in the present embodiment, when the slider 5 is pressed and switched from the off state to the on state, the driving portion 5b is engaged with the driven portion 4b to forcibly tilt the movable contactor 4 to move the movable contactor. When (4) is inclined over the dead point and vigorously directed toward the stationary contactor (3), the slider (5) subjected to the inertial force of the pressing operation pushes the movable contactor (4) from behind through the compression coil spring (6). It is. For this reason, when the contact part 4a of the movable contactor 4 contacts the stationary contactor 3, the elasticity of the compression coil spring 6 can be rapidly increased, and the bounce of this contact part 4a is effective. Can be suppressed. Further, an offset positional relationship in which the compression coil spring 6 is always pushed in at an angle to the connecting end 4d of the movable contact 4 is adopted, so that one side of the point 4c of the movable contact 4 is supported by the support terminal ( Since it is always in elastic contact with the one side concave wall surface 2b of 2), the bounce of the point part 4c which is concerned when switching from an off state to an on state is also suppressed effectively. In addition, in this embodiment, the compression coil spring 6 not only imparts elasticity to the movable contact 4, but also serves as a return spring for automatically returning the pushed slider 5 to its initial position. Since the number can be reduced, it is also advantageous to reduce the cost of the push switch.

The spring member provided between the movable contact 4 and the slider 5 may not necessarily be a compression coil spring, but may be a coil spring or a leaf spring, for example.

The push switch according to the present invention is implemented in the form described above and exhibits the effects as described below.

When the movable contactor is in contact with the stationary contactor, the resilience of the spring member such as the compression coil spring provided between the movable contactor and the slider is rapidly increased, so that the bounce of the movable contactor on the stationary contactor can be greatly suppressed. Therefore, the possibility of contact failure due to burnout by arc heat is low, and reliability and lifespan can be improved.

In addition, the spring member not only imparts elasticity to the movable contact, but also serves as a return spring for automatically returning the pushed slider to the initial position, thereby reducing the number of parts.

In addition, if one side of the portion (point portion) mounted on the support terminal among the movable contacts is always in elastic contact with the wall of the support terminal, the bounce generated by the movable contact on the support terminal is also greatly reduced, further improving reliability and lifespan. Is improved.

Claims (3)

A slider for supporting the movable contactor in an inclined manner at the bottom of the case and a fixed contactor for allowing the movable contactor to come out of contact, and the on / off contact switching by tilting the movable contactor. Is a push switch reciprocally inserted into the case, the spring member being disposed between the slider and one end of the movable contact supported inclinedly on the support terminal, and the reciprocating motion on the slider. And a driving portion for forcibly tilting the movable contact in engagement with a portion of the movable contact, wherein the movable contact itself is pressed against the support terminal through the spring member by pressing the slider when switched on. Push switch. 2. The portion of the movable contact that is mounted on the support terminal according to claim 1, wherein the direction of the elastic force applied to the movable contact from the spring member is set in a direction parallel to the rotational movement surface of the movable contact. A push switch, characterized in that one side is configured to be always in elastic contact with the support terminal wall. The said spring member is a compression coil spring, and attaches the one end of the said movable contact part to the one end of this compression coil spring, and the said drive part of the said slider to the other end of this movable contact part. Push switch, characterized in that provided with a driven portion that can be engaged with.