JPH0129697Y2 - - Google Patents

Description

[Detailed Description of the Invention] The present invention has an extremely simple structure in which each push button is operated by a movable contact piece that is embedded integrally in a holding member made of an insulating material. Even if you press the push buttons at the same time,
This invention relates to a push switch in which no short circuit is formed.

Conventionally, in this type of push switch, 2
In order to prevent the formation of a short circuit due to the simultaneous operation of more than one pushbutton, a restriction member is installed to prevent two or more pushbuttons from being pushed at the same time, or
The formation of short circuits was prevented by increasing the number of movable contact pieces corresponding to the push buttons and by diversifying the connection wiring circuits inside the switch.

That is, as an example, a printed circuit board is used to integrally print the contact portion and the connection wire in a predetermined circuit, and movable contact pieces having complicated shapes corresponding to each push button are fixed to the printed circuit board with grommets or the like. Then, the movable contact piece is guided by a guide plate, and the contact point integrally formed at the free end of the movable contact piece is fixed to the printed circuit board side for pushing the push button via a movable pin that is brought into elastic contact with a spring. There was one that was configured to press and contact the contact surface.

For this reason, all of these conventional push switch configurations have disadvantages such as an increased number of parts and complexity, and a concomitant increase in assembly man-hours and manufacturing costs.

This invention was devised in view of the above-mentioned problems, namely, reduction in the number of component parts, simplification of shape, and significant reduction in assembly man-hours due to improvements in manufacturing methods, resulting in reduction in manufacturing costs. The purpose of the present invention is to provide an inexpensive and high-quality push switch.

DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENTS As a preferred embodiment of the present invention, a remote control mirror switch for remotely controlling an automobile's fender mirror up, down, left, and right will now be described in detail with reference to the accompanying drawings.

1, 2, 3, 4, 5, 6, 7 and 8 show a remote control mirror switch which is an embodiment of the push switch according to the present invention. Yes, 1 and 1' are push buttons,
It has three cylindrical protrusions 1a and 1a' on its lower surface, and holes 1b and 1b' in the center for inserting a spring 3 for automatic return.

2 and 2' are also push buttons, and have two cylindrical protrusions 2a and 2a' on their lower surfaces, respectively, and a spring 3 for automatic return is inserted in the center like the push buttons 1 and 1'. It has holes 2b and 2b'. Reference numeral 4 denotes a housing, and the upper surface side 4a has guide holes 4b, 4b', 4c, and 4 into which the push buttons 1, 1', 2, and 2' are inserted, respectively.
c' is provided. Also, the bottom side 4 which is the back side
d forms an opening into which the base plate 9 is inserted. 5 and 5' are movable plates with movable contact pieces 7a, 7.
b, and movable contact pieces 7b, 7c, respectively, are formed with blade-shaped protrusions 5a and 5a', which are disposed in the housing 4 to face each other.

That is, the guide holes 4b and 4 of the housing 4
The protrusions 1a and 1a' of the push buttons 1 and 1' that protrude inward through the through holes 4b ₁ and 4b' ₁ provided on the bottom surface of the movable plates 5 and 5'
and 5b' and is crimped. 6
and 6' are also movable plates, and have blade-shaped protrusions 6a and 6a' that press the movable contact pieces 7a and 7c, and have the same configuration as the movable plates 5 and 5'.
and 2'. Reference numeral 7 designates a thin plate spring, which is separated into three movable contact pieces 7a, 7b, and 7c having contact points 7a ₁ , 7b ₁ , and 7c ₁ having contact surfaces formed at the tip of one free end, and the other. On the end side, as shown by the imaginary line in FIG. 5, the three pieces are integrally continued at a continuation part 7d, but after being embedded in a holding member 8 made of an insulating material and integrally molded, a predetermined shape is formed. Cut at the C-C line position and continue the section 7d.
is removed, and the movable contact pieces 7a, 7b, and 7c are each independently separated. Reference numeral 9 denotes a base made of an insulating material, in which fixed contact plates 10a, 10b, and 11a are embedded. Also, 9a, 9b,
Reference numeral 9c is a square hole through which the fixed side connection terminal portions 7a ₂ , 7b ₂ , 7c ₂ of the movable contact pieces 7a, 7b, 7c are inserted.

Furthermore, 9d, 9e are movable contact pieces 7a, 7b,
The cylindrical protrusions 8a and 8b installed on the holding member 8 of 7c are holes into which they are respectively fitted.

Fixed contact plates 10a and 10b are embedded in the base plate 9, and are integrally formed with a connecting terminal portion 10 protruding from the outer surface of the base plate 9. Further, the contact plates 10a and 10b are buried perpendicularly to the plane of the base plate 9 as shown by the imaginary lines in FIG. That's what happens. The fixed contact plate 11a is exposed and buried in the inner surface 9f of the base plate 9, and has the connecting terminal portion 11 protruding from the outer surface. Reference numeral 12 denotes a connection cord, which connects the connection terminal portions 7a ₂ , 7b ₂ , 7c ₂ of the movable contact pieces 7 a , 7 b , 7 c protruding from the outer surface of the base plate 9 and the fixed contact plate 10 .
Connection terminal part 10 and fixed contact plate 11 of a and 10b
They are respectively connected to the connection terminal portions 11 of a. 13 are respective fasteners for attaching the base 9 to the housing 4.

In addition, in FIG. 8, 14 is a remote control mirror switch which is an embodiment of the push switch according to the present invention. 15 is a mirror, which is attached to the fender of the automobile.

15a is a motor included in the mirror 15, 15b is a solenoid, and 20 is a lock switch. Reference numeral 16 denotes a power source, which shows an electric circuit with the remote control mirror switch 14.

Furthermore, the blade-shaped protrusions 5a, 5a', 6a and 6a' of the movable plates 5, 5', 6 and 6' and the movable contact piece 7a,
The correspondence relationship between 7b and 7c is as shown by the imaginary line in FIG. The protrusion 5a of the movable platen 5 comes into contact with the movable contact pieces 7a and 7b when lowered. The protrusion 5a' of the movable platen 5' comes into contact with the movable contact pieces 7b and 7c when lowered. Movable plate 6
The protrusion 6a contacts the movable contact piece 7a when lowered. The protrusion 6a' of the movable platen 6' comes into contact with the movable contact piece 7c when lowered.

Next, the electrical circuit connection structure of a remote control mirror switch, which is an embodiment of the push switch according to the present invention, will be described in detail.

The electrical circuit diagram of the remote control mirror switch 14 is connected as shown in FIG. That is, the movable contact piece 7a is connected to the mirror 1 from its connecting terminal portion _7a2 .
It is connected to one of the motors 15a of No. 5. The movable contact piece 7c connects the mirror 1 from its connection terminal portion _7c2 .
It is connected to the other motor 15a of No. 5. Further, the movable contact piece 7b is connected to the negative electrode of the power source 16 via the solenoid 15b of the mirror 15 from its connecting terminal portion _7b2 . Fixed contact plates 10a, 10
b is connected to the negative electrode of the power source 16 through its connection terminal portion 10. The fixed contact plate 11a is connected from the connecting terminal portion 11 to the positive pole of the power source via the lock switch 20.

Next, the operation of the remote control mirror switch, which is an embodiment of the push switch according to the present invention having the above structure, will be explained.

Push buttons 1, 1' of remote control mirror switch 14,
In a normal state in which push buttons 2 and 2' are not pressed in any way, the push buttons 1, 1', 2, and 2' are biased by their respective springs 3 and raised. The upper surfaces of movable plates 5, 5', 6, and 6' installed at the lower ends of the push buttons 1, 1', 2, and 2' are in contact with the housing 4. For this reason, movable plates 5, 5', 6, 6'
are not in contact with the movable contact pieces 7a, 7b, and 7c.
The contact 7a ₁ of the movable contact piece 7a is in contact with the fixed contact plate 10a with a predetermined spring pressure applied in advance to the movable contact piece 7a. Contact point 7 of movable contact piece 7c
The movable contact _piece 7c is in contact with the fixed contact plate 10b with a predetermined spring pressure. The contact _7b1 of the movable contact piece 7b is connected to the opposing fixed contact plate 11a.
It remains in the OFF state for a predetermined period of time. Therefore, the voltage of the power supply 16 is not applied to the remote control mirror switch, and it is in an OFF state.

Next, when the left push button 2 is pushed, the push button 2 and the movable platen 6 fixed to the push button 2 are lowered. The movable platen 6 presses the movable contact piece 7a with the tip of the blade-shaped protrusion 6a to lower it. The contact 7a ₁ of the movable contact piece 7a is separated from the fixed contact plate 10a and comes into contact with the fixed contact plate 11a. The movable contact piece 7c is not pressed and the contact point _7c1 is in contact with the fixed contact plate 10b. Here, since the fixed contact plate 11a is connected to the positive pole of the power source 16, the current from the power source 16 is transmitted to the fixed contact plate 11a, the movable contact piece 7a, the motor 15a, the movable contact piece 7c, the fixed contact plate 10b, and the power source 16. The motor 15a rotates, and the mirror 15a rotates in the left-right direction.

Next, the action when the right push button 2' is pushed will be explained in detail.

When the right push button 2' is pushed, the push button 2' and the movable platen 6' fixed to the push button 2' are lowered. The movable platen 6' presses the movable contact piece 7c with the tip of the blade-shaped protrusion 6a' to lower it. and,
The contact 7c ₁ of the movable contact piece 7c is connected to the fixed contact plate 10b.
It moves further away and contacts the fixed contact plate 11a. Then, the current from the power source 16 flows to the fixed contact plate 11a, the movable contact piece 7c, the motor 15a, the movable contact piece 7a, the fixed contact plate 10a, and the negative electrode of the power source 16, so the motor 15a rotates.

In this case, since the direction of the current flowing to the motor 15a is opposite to that when the one (left) push button 2 is pressed, the mirror 15 is driven in the opposite direction, that is, to the right.

Next, the effect when the upper push button 1 is pushed will be explained in detail.

When the upper push button 1 is pushed, the push button 1 and the movable platen 5 fixed to the push button 1 are lowered. The movable platen 5 presses the movable contact pieces 7a and 7b together with the tip of the blade-shaped protrusion 5a to lower them. The protrusion 5
The tip end of a has a stepped shape in which the heights are different at the points where the movable contact piece 7a and the movable contact piece 7b come into contact. Therefore, first, the contact _7b1 of the movable contact piece 7b contacts the fixed contact plate 11a, and then, after an instant of delay, the contact _7a1 of the movable contact piece 7a separates from the fixed contact plate 10a and contacts the fixed contact plate 11a. Contact. Since the movable contact piece 7c is not pressed, the contact point _7c1 is in contact with the fixed contact plate 10b. Then, the current 16 first flows from the power supply 16 to the fixed contact plate 11a and the movable contact piece 7.
b, solenoid 15b, and the negative electrode of the power source 16, so that the mirror 15 is installed at a position where the drive direction of the mirror 15 is changed by 90 degrees with respect to the leftward drive due to the action of the solenoid 15b. Subsequently, the current from the power source 16 flows to the fixed contact plate 11a, the movable contact piece 7a, the movable contact piece 7c of the motor 15a, the fixed contact plate 10b, and the negative electrode of the power source 16 in parallel with the energization of the solenoid 15b, so that the motor The mirror 15 is driven upward by the rotation of the mirror 15a.

Next, the operation when the lower push button 1' is pushed will be explained in detail.

When the lower push button 1' is pushed, the push button 1' and the movable platen 5' fixed to the push button 1' are lowered. The movable platen 5' presses the movable contact pieces 7b and 7c together with the tip of the blade-shaped protrusion 5a' to lower them. The tip of the protruding portion 5a' has a step shape in which the heights are different at the points where the movable contact piece 7b and the movable contact piece 7c come into contact. Therefore, first, the movable contact piece 7b
The contact _7b1 of the movable contact piece 7c comes into contact with the fixed contact plate 11a, and then, after a momentary delay, the contact _7c1 of the movable contact piece 7c leaves the fixed contact plate 10b and comes into contact with the fixed contact plate 11a. The movable contact piece 7a is not pressed, and the upper side of the contact point _7a1 is in contact with the fixed contact plate 10a. Then, the current first flows from the power source 16 to the fixed contact plate 11a, the movable contact piece 7b, the solenoid 15b, and the negative electrode of the power source 16, and changes to a position converted by 90 degrees with respect to the rightward drive. Subsequently, the current from the power source 16 is applied to the fixed contact plate 11a, the movable contact piece 7c, and the motor 15.
a, movable contact piece 7a, fixed contact plate 10a, power supply 16
The current flows to the negative electrode of the solenoid 15b in parallel with the energization of the solenoid 15b. In this case, since the direction of the current flowing to the motor 15a is opposite to that when the upper push button 1 is pressed, the mirror 15 is driven in the opposite direction, that is, in the downward direction.

Also, if the lock switch 20 is opened after adjusting the mirror position, each push button 1, 1', 2,
Even if 2' is pushed, the adjusted position can be maintained and there will be no malfunction. This lock switch 20 may be provided separately, or may be integrated with the left/right selector switch 21 as shown in FIGS. 9 and 10.

Next, a description will be given of the effect that a short circuit is not formed when two or more push buttons are pressed at the same time.

When the left and right push buttons 2, 2' are pushed simultaneously, the push buttons 2, 2' and the movable plates 6, 6' are lowered. The movable plates 6, 6' have blade-shaped protrusions 6a,
6a' simultaneously presses the movable contact pieces 7a and 7c and lowers them. Contact points 7a 1 and 7c ₁ of the movable contact pieces 7a and _7c
Both contact the fixed contact 11a. For this reason,
The movable contact piece 7a connected to one terminal of the motor 15a and the movable contact piece 7c connected to the other terminal of the motor 15a are both connected to the fixed contact 11a connected to the positive terminal of the power source 16, so the ground circuit is interrupted. Therefore, no electric circuit is formed and no operation occurs.

Next, the operation when the upper and lower push buttons 1 and 1' are pushed simultaneously will be explained in detail.

When the upper and lower push buttons 1, 1' are pushed simultaneously, the push buttons 1, 1' and the movable plates 5, 5' are lowered. The movable plates 5, 5' have blade-shaped protrusions 5a,
5a' presses the three movable contact pieces 7a, 7b, 7c together and lowers them. The movable contact pieces 7a, 7b, 7c
The contacts 7a ₁ , 7b ₁ , 7c ₁ are all fixed contacts 11a
come into contact with. Therefore, the motor 15a does not operate because the ground circuit is not formed in the same manner as described above. Also, the solenoid 15 connected to the negative pole of the power supply 16
Since a circuit connected to the positive electrode of the power source 16 is formed from the movable contact piece 7b, only the solenoid 15b is energized.

Next, the effect when push button 1 and push button 2 are pushed simultaneously will be explained in detail.

If you press push button 1 and push button 2 at the same time,
Push buttons 1 and 2 and movable plates 5 and 6 are lowered. The protrusion 5a of the movable platen 5 presses and lowers the movable contact pieces 7a and 7b, and the protrusion 6a of the movable platen 6 presses the movable contact pieces 7a and 7b.
Press a to lower it. The contacts 7a ₁ and 7b ₁ of the movable contact pieces 7a and 7b both contact the fixed contact plate 11a. Since the movable contact piece 7c is not pressed, the upper side of the contact point _7c1 is in contact with the fixed contact plate 10b.
Since the current flows from the power source 16 to the fixed contact plate 11a, the movable contact piece 7b, the solenoid 15b, and the negative electrode of the power source 16, the driving direction of the mirror 15 is changed upward by the action of the solenoid 15b. In addition, the current flows from the power source 16 to the fixed contact plate 11a, to the movable contact piece 7.
a, the motor 15a, the movable contact piece 7c, the fixed contact plate 10b, the negative electrode of the power source 16, and the solenoid 1
Flows in parallel with the energization to 5b. That is, when the push button and the push button 1' are operated simultaneously, the mirror 15 has the same effect as when the push button 1 is pushed alone, and the mirror 15 is mirror-driven upward.

Next, the operation when push button 1' and push button 2' are pushed simultaneously will be explained in detail.

When the push buttons 1' and 2' are pushed simultaneously, the push buttons 1', 2' and the movable plates 5', 6' are lowered. The protrusion 5a' of the movable platen 5' has movable contact pieces 7b,
7c and lower it to remove the protrusion 6 of the movable plate 6'.
a' presses the movable contact piece 7c to lower it. The contacts 7b ₁ and 7c _{1 of the movable contact pieces 7b and 7c} both contact the fixed contact plate 11a. Since the movable contact piece 7a is not pressed, the upper side of the contact point _7a1 is in contact with the fixed contact plate 10b. Since the current flows from the power source 16 to the fixed contact plate 11a, the movable contact piece 7b, the solenoid 15b, and the negative electrode of the power source 16, the driving direction of the mirror 15 is changed downward by the action of the solenoid 15b. In addition, the current flows from the power source 16 to the fixed contact plate 1.
1a, the movable contact piece 7c, the motor 15a, the movable contact piece 7a, the fixed contact plate 10a, and the negative electrode of the power source 16.
The current flows in parallel with the energization of the solenoid 15b.
In other words, if push button 1' and push button 2' are operated at the same time,
The mirror 15 has the same effect as when the push button 1' is pressed individually, and the mirror 15 is driven downward.

Furthermore, when three or more push buttons are pressed simultaneously, the movable contact piece 7b is connected to the positive fixed contact 11a of the power source 16, so that only the solenoid current is energized. In any of the above cases, a short circuit is not formed.

As explained above, the push switch according to the present invention has the following effects.

(b) The number of component parts is small, the shape of the component parts is simplified, and the manufacturing method is improved. In other words, the movable contact piece for opening and closing the electric circuit is made of an insulating material that holds the movable contact piece. By being integrally molded into the component, the number of assembly steps can be significantly reduced, and a push switch with stable quality and low manufacturing costs can be provided.

(b) Even if two or more push buttons are pushed, there is no risk of causing a short circuit accident.

(c) Since the positive potential of the power supply is not applied to the circuit connected to the motor etc. under normal conditions, problems such as electrolytic corrosion will not occur.

[Brief explanation of the drawing]

FIG. 1 is a plan view of a push switch according to the present invention. FIG. 2 is a sectional view taken along the line A--A in FIG. 1. Figure 3 shows the arrow B- in Figure 2.
FIG. 3 is a cross-sectional view in the direction of line B. FIG. 4 is a side view of the base of the push switch according to the present invention, and is an explanatory view showing the steps in which the fixed contact plate is integrally molded to the base and then bent into a predetermined position. Fifth
The figure is an explanatory diagram showing a procedure in which the three movable contact pieces of the push switch according to the present invention are integrally molded with the holding member, and then the continuation portions are cut and removed to separate them into individual pieces. FIG. 6 is a perspective view of the components of the push switch according to the present invention, in which the push button, spring, housing, and movable plate are sub-assembled.
FIG. 7 is a perspective view showing the components of the push switch according to the present invention. FIG. 8 is an electrical circuit diagram of a remote control mirror switch showing an embodiment of the push switch according to the present invention. Figures 9 and 10
The figure is an overall perspective view showing an embodiment of the push switch according to the present invention. 1, 1', 2, 2'...Push button, 4...Housing, 5, 5', 6, 6'...Movable plate, 7a, 7b,
7c...Movable contact piece, 8...Holding member, 9...Base, 10a, 11a...Fixed contact plate, 14...Remote control mirror switch, 15a...Motor, 1
5b...Solenoid.

Claims (1)

[Scope of utility model registration request] four push buttons that are inserted into the housing via springs and have protrusions that penetrate into the housing; a housing that is provided with through holes for penetrating the protrusions of the four push buttons; Four movable plates arranged at the tips of the protrusions and having protrusions for pressing the movable contact pieces, arranged correspondingly to the lower parts of the four movable plates, and having contacts in the vertical direction of the tips. A movable contact piece structure consisting of two movable contact pieces and one movable contact piece having a contact point downward at the tip thereof, and a movable contact piece structure that is integrally arranged in parallel to hold the three movable contact pieces. A holding member with a protruding connecting end of the ends of the three movable contact pieces, and two L-shaped fixed contacts arranged to contact the upper sides of the two movable contact pieces having contacts in the vertical direction. A connecting terminal portion having a connecting terminal portion integrally formed with a plate and a fixed contact plate disposed to contact the three movable contact pieces, the two connecting terminal portions being insert molded, and the holding member A push switch comprising a base mounted on the housing and fitted into the housing.