JP2013058393A - Slide contact switch - Google Patents

Abstract

PROBLEM TO BE SOLVED: To solve the problems of burning of components due to heat generation and easy occurrence of insulation breakage between contacts points that result from increase in spark geneartion at swtiching points and increase in contact resistance at contact point when switching rate reduces in a conventional slide contact switch that switches contact points through manual operation.SOLUTION: In a slide contact switch A for switching a contact point in which a slider 20 moves in a casing 10 in a click-stop manner, an action part for operating the slider is provided on the casing, and a predetermined play S is provided on the action part in actuating the slider. Even when an operation speed of an action part becomes low, a contact point is spontaneously switched in a click-stop manner with the slider. Spark occurs normally at a switching point and contact resistance at the contact point is not increased even when the contact switching speed becomes low due to manual operation, thus, unlike a conventional one, a component is not burned by heat generation or insulation breakage between the contact points does not occur.

Description

    The present invention relates to a slide contact switch, and is used for, for example, a light switch, a turn switch, a forward / reverse switch, a speed switch and the like in a vehicle.

    In this type of conventional slide contact switch, a slider is installed in a casing, and the contact is switched by moving the slider in a click-stop manner via a knob.

JP 2006-59766 A

    However, in such a conventional slide contact switch, since the contact is switched by manual operation, if the switching speed becomes slow, the occurrence of sparks at the switching point increases and the contact contact resistance increases. It had the inconvenience that it burned out and the dielectric breakdown between the contacts was likely to occur.

    An object of the present invention is to eliminate these disadvantages.

    In order to eliminate the inconvenience, in the slide contact switch according to the present invention, in the slide contact switch in which the slider moves in a click stop manner in the casing and the contact is switched, an action portion for operating the slider is provided in the casing. The action portion is provided with a predetermined play when operating the slider.

    In this case, the action portion includes a guide member fixed to the casing and a knob member that slides along the guide member, and the knob member slides along the guide member to collide with the slider. The click stop mechanism of the slider can be operated by pushing it out.

    Further, the knob member can be locked to the guide member.

    The knob member can be locked to the slide end of the guide member.

    Since the slide contact switch according to the present invention is configured as described above, that is, in the slide contact switch in which the slider moves in a click-stop manner in the casing and switches the contact, the action of operating the slider on the casing Since the action portion is provided with a predetermined play when the slider is operated, the click-stop contact by the slider is instantaneously switched even if the operation speed of the action portion is reduced.

    Therefore, if this light contact switch is used, even if the contact switching speed is slowed down by manual operation, the spark generation at the switching point is normal and the contact contact resistance does not increase. Parts are not burned off due to heat generation, and dielectric breakdown between the contacts does not occur.

    In this case, the action portion includes a guide member fixed to the casing and a knob member that slides along the guide member, and the knob member slides along the guide member to collide with the slider. If the click stop mechanism of the slider is operated by pushing it out, play can be provided in the action portion with a simple structure.

    If the knob member can be locked to the guide member, the play in the movement of the knob member can be maintained constant.

    If the knob member can be locked to the slide end of the guide member, the play can be maximized.

    The light contact switch according to the present invention has the following main features when implemented.

    The slider moves in a click-stop manner in the casing to selectively switch the contacts.

    An action part for operating the slider is provided in the casing. The action portion includes a guide member fixed to the casing and a knob member that slides along the guide member. The knob member slides along the guide member, collides with the slider, and pushes the slider to operate the click stop mechanism of the slider.

    The knob member can be locked to the slide end of the guide member.

Embodiments of the present invention will be described below with reference to the drawings.
1 is a cross-sectional view before switching the slide contact switch according to the present invention, FIG. 2 is a cross-sectional view immediately before the switching, FIG. 3 is a cross-sectional view after the switching, and FIG. It is sectional drawing.

    1-4, A is a slide contact switch and 10 is its casing. Reference numerals 11 and 12 denote first click recesses, which are formed on the inner wall surface of the bottom of the casing 10. A first click ball 22 to be described later is engaged with the first click recesses 11 and 12. Reference numeral 13 denotes a slide hole for sliding a protruding portion of the knob member 40 described later.

    Reference numeral 20 denotes a slider which is slidably fitted in the casing 10. The contact is switched by the movement of the slider 10. The contact is not shown. Reference numeral 21 denotes a mounting hole formed on the lower surface of the slider 20. The mounting hole 21 opens toward the contact surface of the casing 10. Reference numeral 22 denotes a first click ball, which is installed in the mounting hole 21. The first click ball 22 is ejected to the outside by the first compression coil spring 23, and the tip portion is selectively locked to the first click recesses 11 and 12.

    Reference numerals 24 and 25 denote collision receiving portions, which are formed on upper portions on both sides of the slider 20. The collision receiving portions 24 and 25 are arranged in a state of facing each other.

    Reference numeral 30 denotes a guide member, which is installed in the casing 10. The guide surface 31 of the guide member 30 is along the sliding direction of the slider 20. Reference numerals 32 and 33 denote second click recesses, which are formed at both ends of the guide surface 31 of the guide member 30. A second click ball 42 to be described later is engaged with the second click recesses 32 and 33.

    Reference numeral 40 denotes a knob member that slides on the upper inner wall surface of the casing 10 along the guide surface 31 of the guide member 30. The upper end portion of the knob member 40 protrudes from the slide hole 13 of the casing 10. The knob member 40 is operated through the protruding portion. Reference numeral 41 denotes a mounting hole, which is formed on the lower surface of the knob member 40. The mounting hole 41 opens toward the guide surface 31 of the guide member 30. Reference numeral 42 denotes a second click ball, which is installed in the mounting hole 41. The second click ball 42 is springed outward by the second compression coil spring 43, and the tip portion is engaged with the second click recesses 32 and 33.

    The second click recesses 32 and 33 are shallower than the first click recesses 11 and 12, and the elasticity of the second compression coil spring 43 is weaker than the elasticity of the first compression coil spring 23. The click stop of the knob member 40 relative to the guide member 30 is lighter than the click stop of the slider 20 relative to the casing 10, and the knob member 40 relative to the guide member 30 moves with priority.

    Reference numerals 44 and 45 denote collision parts, which protrude from both side surfaces of the knob member 40. The collision portions 44 and 45 are portions that collide with the collision receiving portions (of the slider 20) 24 and 25. The slide range S of the collision portions 44 and 45 corresponds to “play” of the present invention.

    The guide member 30 and the knob member 40 constitute an “action member” of the present invention.

    Next, the operation of the slide contact switch A will be described.

    FIG. 1 shows a state before contact switching. The slider 20 is positioned on the left side of the casing 10, and the first click ball 22 is engaged with the first click recess 11. The knob member 40 is located at the left end of the guide member 30, and the second click ball 42 is engaged with the second click recess 32. At this time, the collision portion 44 of the knob member 40 is in contact with the collision receiving portion 24 of the slider 20.

    In this state, the knob member 40 is moved in the right direction against the elasticity of the second compression coil spring 43, and the collision portion (of the knob member 40) 45 is subjected to the collision receiving of the slider 20, as shown in FIG. Collide with part 25. In this state, the slider 20 is further pressed against the elasticity of the first compression coil spring 23 by the knob member 40, and the slider 20 is positioned on the right side of the casing 10 as shown in FIG. The one-click ball 22 is engaged with the first click recess 12 to be in a state after switching the contact. At this time, the knob member 40 is positioned at the right end of the guide member 30, and the second click ball 42 is engaged with the second click recess 33. Further, the collision part 45 of the knob member 40 is in contact with the collision receiving part 25 of the slider 20.

    When returning to the state before the contact switching (the state shown in FIG. 1), an operation opposite to the switching operation may be performed. That is, the knob member 40 is moved in the left direction against the elasticity of the second compression coil spring 43, and the collision portion (of the knob member 40) 44 is moved to the collision receiving portion of the slider 20 as shown in FIG. In this state, the slider 20 may be further pressed against the elasticity of the first compression coil spring 23 by the knob member 40 to obtain the state shown in FIG.

In the slide contact switch according to the present invention, even if the operation speed of the action unit is slow, the click-stop type contact switching by the slider is instantaneously performed. Even if the contact switching speed is slowed down by manual operation, sparks are generated at the switching point as usual and the contact contact resistance does not increase. There is no breakdown. Therefore, industrial applicability is high.

FIG. 1 is a cross-sectional view before switching a slide contact switch according to the present invention. FIG. 2 is a sectional view immediately before the switching. FIG. 3 is a cross-sectional view after the switching. FIG. 4 is a cross-sectional view immediately after returning from the same switching and before switching.

A ... Slight contact switch 10 ... Casing 11 ... First click recess 12 ... First click recess 13 ... Slide hole 20 ... Slider 21 ... Mounting hole 22 ... First click ball 23 ... First compression coil spring 24 ... Impact receiving Part 25 ... Collision receiving part 30 ... Guide member (action member)
31 ... Guide surface 32 ... Second click recess 33 ... Second click recess 40 ... Knob member (action member)
41 ... Mounting hole 42 ... Second click ball 43 ... Second compression coil spring 44 ... Collision part 45 ... Collision part S ... Slide range (play)

    The present invention relates to a slide contact switch, and is used for, for example, a light switch, a turn switch, a forward / reverse switch, a speed switch and the like in a vehicle.

    In this type of conventional slide contact switch, a slider is installed in a casing, and the contact is switched by moving the slider in a click-stop manner via a knob.

JP 2006-59766 A

    However, in such a conventional slide contact switch, since the contact is switched by manual operation, if the switching speed becomes slow, the occurrence of sparks at the switching point increases and the contact contact resistance increases. It had the inconvenience that it burned out and the dielectric breakdown between the contacts was likely to occur.

    An object of the present invention is to eliminate these disadvantages.

    In order to eliminate the inconvenience, in the slide contact switch according to the present invention, a casing, a slider that slides on the inner wall surface of the bottom of the casing, a guide member fixed above the slider in the casing, and the guide member A knob member that slides, and a collision receiving portion on which the knob member collides is formed on both upper sides of the slider, and the knob member has a sliding range between the collision receiving portion, A pair of V-shaped first click recesses are formed adjacent to each other on the bottom inner wall surface of the casing, and a first click ball is selected as the pair of first click recesses on the lower surface of the slider. And a second click recess is formed at each end of the guide surface of the guide member. And a second click ball is elastically installed on the lower surface of the knob member so as to be engaged with the pair of second click recesses, and the slider and the knob member slide in the same direction, When the click ball is locked to the one first click recess, the knob member is colliding with a collision receiving portion on the same side of the slider, and the second click ball is in contact with the first click recess. The knob member can be locked in the second click recess on the same side, and when the first click ball is locked in the other first click recess, the knob member is the collision receiving portion on the other side of the slider And the second click ball can be locked to the other second click recess, the second click recess is shallower than the first click recess, and the second compression coil Spring bullet It is obtained by weaker than the elasticity of the first compression coil spring.

In this case, the first click ball can instantaneously select the pair of first click recesses.

    In addition, the casing is provided with a slide hole through which the protruding portion of the knob member slides, and when the first click ball is engaged with the one first click recess, the protruding portion of the knob member is the slide hole. When the first click ball is locked to the other first click recess, the protrusion of the knob member is positioned at the other end of the slide hole. It can also be done.

    Since the slide contact switch according to the present invention is configured as described above, the click-stop contact switching by the slider is instantaneously performed even if the operation speed of the action unit is slow.

    Therefore, if this light contact switch is used, even if the contact switching speed is slowed down by manual operation, the spark generation at the switching point is normal and the contact contact resistance does not increase. Parts are not burned off due to heat generation, and dielectric breakdown between the contacts does not occur.

In this case, the first click ball can instantaneously select the pair of first click recesses.

In addition, the casing is provided with a slide hole through which the protruding portion of the knob member slides, and when the first click ball is engaged with the one first click recess, the protruding portion of the knob member is the slide hole. When the first click ball is locked to the other first click recess, the protrusion of the knob member is positioned at the other end of the slide hole. It can also be done.

    The light contact switch according to the present invention has the following main features when implemented.

    The slider moves in a click-stop manner in the casing to selectively switch the contacts.

    An action part for operating the slider is provided in the casing. The action portion includes a guide member fixed to the casing and a knob member that slides along the guide member. The knob member slides along the guide member, collides with the slider, and pushes the slider to operate the click stop mechanism of the slider.

    The knob member can be locked to the slide end of the guide member.

Embodiments of the present invention will be described below with reference to the drawings.
1 is a cross-sectional view before switching the slide contact switch according to the present invention, FIG. 2 is a cross-sectional view immediately before the switching, FIG. 3 is a cross-sectional view after the switching, and FIG. It is sectional drawing.

    1-4, A is a slide contact switch and 10 is its casing. Reference numerals 11 and 12 denote first click recesses, which are formed on the inner wall surface of the bottom of the casing 10. A first click ball 22 to be described later is engaged with the first click recesses 11 and 12. Reference numeral 13 denotes a slide hole for sliding a protruding portion of the knob member 40 described later.

    Reference numeral 20 denotes a slider which is slidably fitted in the casing 10. The contact is switched by the movement of the slider 10. The contact is not shown. Reference numeral 21 denotes a mounting hole formed on the lower surface of the slider 20. The mounting hole 21 opens toward the contact surface of the casing 10. Reference numeral 22 denotes a first click ball, which is installed in the mounting hole 21. The first click ball 22 is ejected to the outside by the first compression coil spring 23, and the tip portion is selectively locked to the first click recesses 11 and 12.

    Reference numerals 24 and 25 denote collision receiving portions, which are formed on upper portions on both sides of the slider 20. The collision receiving portions 24 and 25 are arranged in a state of facing each other.

    Reference numeral 30 denotes a guide member, which is installed in the casing 10. The guide surface 31 of the guide member 30 is along the sliding direction of the slider 20. Reference numerals 32 and 33 denote second click recesses, which are formed at both ends of the guide surface 31 of the guide member 30. A second click ball 42 to be described later is engaged with the second click recesses 32 and 33.

    Reference numeral 40 denotes a knob member that slides on the upper inner wall surface of the casing 10 along the guide surface 31 of the guide member 30. The upper end portion of the knob member 40 protrudes from the slide hole 13 of the casing 10. The knob member 40 is operated through the protruding portion. Reference numeral 41 denotes a mounting hole, which is formed on the lower surface of the knob member 40. The mounting hole 41 opens toward the guide surface 31 of the guide member 30. Reference numeral 42 denotes a second click ball, which is installed in the mounting hole 41. The second click ball 42 is springed outward by the second compression coil spring 43, and the tip portion is engaged with the second click recesses 32 and 33.

    The second click recesses 32 and 33 are shallower than the first click recesses 11 and 12, and the elasticity of the second compression coil spring 43 is weaker than the elasticity of the first compression coil spring 23. The click stop of the knob member 40 relative to the guide member 30 is lighter than the click stop of the slider 20 relative to the casing 10, and the knob member 40 relative to the guide member 30 moves with priority.

    Reference numerals 44 and 45 denote collision parts, which protrude from both side surfaces of the knob member 40. The collision portions 44 and 45 are portions that collide with the collision receiving portions (of the slider 20) 24 and 25. The slide range S of the collision portions 44 and 45 corresponds to “play” of the present invention.

    The guide member 30 and the knob member 40 constitute an “action member” of the present invention.

    Next, the operation of the slide contact switch A will be described.

    FIG. 1 shows a state before contact switching. The slider 20 is positioned on the left side of the casing 10, and the first click ball 22 is engaged with the first click recess 11. The knob member 40 is located at the left end of the guide member 30, and the second click ball 42 is engaged with the second click recess 32. At this time, the collision portion 44 of the knob member 40 is in contact with the collision receiving portion 24 of the slider 20.

In this state, the knob member 40 is moved in the right direction against the elasticity of the second compression coil spring 43, and the collision portion (of the knob member 40) 45 is subjected to the collision receiving of the slider 20, as shown in FIG. Collide with part 25. In this state, the slider 20 is further pressed against the elasticity of the first compression coil spring 23 by the knob member 40, and the slider 20 is positioned on the right side of the casing 10 as shown in FIG. The one-click ball 22 is engaged with the first click recess 12 to be in a state after switching the contact. At this time, the knob member 40 is positioned at the right end of the guide member 30, and the second click ball 42 is engaged with the second click recess 33. Also,
The collision part 45 of the knob member 40 is in contact with the collision receiving part 25 of the slider 20.

    When returning to the state before the contact switching (the state shown in FIG. 1), an operation opposite to the switching operation may be performed. That is, the knob member 40 is moved in the left direction against the elasticity of the second compression coil spring 43, and the collision portion (of the knob member 40) 44 is moved to the collision receiving portion of the slider 20 as shown in FIG. In this state, the slider 20 may be further pressed against the elasticity of the first compression coil spring 23 by the knob member 40 to obtain the state shown in FIG.

In the slide contact switch according to the present invention, even if the operation speed of the action unit is slow, the click-stop type contact switching by the slider is instantaneously performed. Even if the contact switching speed is slowed down by manual operation, sparks are generated at the switching point as usual and the contact contact resistance does not increase. There is no breakdown. Therefore, industrial applicability is high.

FIG. 1 is a cross-sectional view before switching a slide contact switch according to the present invention. FIG. 2 is a sectional view immediately before the switching. FIG. 3 is a cross-sectional view after the switching. FIG. 4 is a cross-sectional view immediately after returning from the same switching and before switching.

A ... Slight contact switch 10 ... Casing 11 ... First click recess 12 ... First click recess 13 ... Slide hole 20 ... Slider 21 ... Mounting hole 22 ... First click ball 23 ... First compression coil spring 24 ... Impact receiving Part 25 ... Collision receiving part 30 ... Guide member (action member)
31 ... Guide surface 32 ... Second click recess 33 ... Second click recess 40 ... Knob member (action member)
41 ... Mounting hole 42 ... Second click ball 43 ... Second compression coil spring 44 ... Collision part 45 ... Collision part S ... Slide range (play)

Claims (4)

In a slide contact switch in which the slider moves in a click-stop manner in the casing and switches the contact, an action portion for operating the slider is provided in the casing, and a predetermined play is provided in the action portion for operating the slider. Slight contact switch characterized by that. The action portion includes a guide member fixed to the casing and a knob member that slides along the guide member. The knob member slides along the guide member, collides with the slider, and is pushed out. 2. The slide contact switch according to claim 1, wherein a click stop mechanism of the slider is operated. The slide contact switch according to claim 2, wherein the knob member can be locked to the guide member. 4. The slide contact switch according to claim 3, wherein the knob member can be locked to a slide end of the guide member.

Images