JPS6032939B2 - illuminated switch - Google Patents

Description

DETAILED DESCRIPTION OF THE INVENTION The present invention relates to an illuminated switch which can be turned on and off without contact and which can illuminate the front surface of the switch.

Conventionally, this type of switch has a contact point, so it has a short lifespan and is prone to failure.In addition, the ON/OFF operation must be performed against spring force, requiring a large pressing force, or
, there are drawbacks such as slow response to OFF operation.

This invention solves the above drawbacks and turns on and off without contact.
The purpose of the present invention is to provide an illuminated switch which has a long service life, is easy to turn on and off, and has a fast response.

Embodiments of the present invention will be described below with reference to the drawings.

As shown in FIG. 1, a plurality of light emitting elements 1 such as light emitting diodes and light receiving elements 2 such as phototransistors are set on a lead frame 3 and have a translucent resin 4 and a condensing lens surface 5a. They are each molded with a translucent resin 5, and the light-receiving surface side thereof is covered with a light-scattering plate 6, and at the interface between the resins 4 and 5, the light emitted L from the light-emitting element 1 is directly directed to the light-receiving element 2. A reflective layer 7 is formed to prevent light from being received. Further, 8 is an opaque resin forming the outer sphere. FIG. 2 is an electric circuit diagram showing an example of an illuminated switch according to the present invention, in which a light receiving element 2 is connected between power terminals P, P2 via a resistor R, and the output side of the light receiving element 2 is is connected to a retrigger monostable multipipelator MSM via a NOT circuit NOT, and the output of this piperator MSM is connected to a binary counter, for example, a D flip-flop circuit DFF, and the set output of this DFF circuit is connected to an exclusive OR circuit ExOR. A pulse oscillator OSC is connected to one input terminal of this EXOR circuit.
is connected.

The light emitting element 1 is connected between the output end of the E-phantom OR circuit and the positive power supply terminal P via a resistor R2.

R is a resistor that together with a capacitor C constitutes a time constant circuit. Next, the operation of the above configuration will be explained.

(1) Regarding the ON operation of the switch: While the oscillator OSC generates a clock pulse a as shown in Figure 3A, the DFF circuit is in a reset state when the power is turned on, so its Q terminal The output b is at the logic level "0" as shown in FIG. 3B, and the output from the Q terminal is at the logic level "1".

In this way, at time tl, clock pulse a is "1",
Since the output b force of the Q terminal of the DFF circuit is 0'', EX
The output c of the OR circuit becomes "1", and the light emitting element 1 is not driven and is in an off state. Here, logic level "0" indicates almost the same potential as the P2 terminal, and logic level "1" indicates the PI terminal.
Shows almost the same potential as the terminal.

Therefore, since the light emitting element 1 is turned off at time tl, even if the fingers are placed opposite each other as shown in FIG. It remains '1' like E.Next, at time t2, when the clock pulse a from the oscillator OSC becomes '0', the output b of the Q terminal of the DFF circuit remains '0'. Therefore, the output c of the ExOR circuit becomes "0", and the light emitting element 1 lights up upon receiving the pulse d as shown in FIG. 4D.

In this way, the output e of the light receiving element 2 changes from "1" to "0" with a slight time delay from time tl to time t2, and the output f of the NOT circuit becomes "1". This output f
The rising edge of the pulse activates the MSM circuit and its output g becomes "1". Therefore, the DFF circuit operates and Q
The output b of the terminal becomes "1". When the output b becomes "1", since the clock pulse a is "0" until time t3, the output c is "1", and the light emitting element 1 is temporarily turned off.

That is, the light emitting element 1 is momentarily turned off by the finger. By turning off the light, the output e becomes "1" and the output f becomes "0", which continues until the point in time.On the other hand, since the MSM circuit is activated by the rising edge of the input pulse, the output f becomes "0". does not change, so the level of the output b of the MSM circuit also does not change.

When the clock pulse a becomes "1" at the time point, since the output b is "1", the output c becomes "0".

Therefore, the light emitting element 1 is lit by the pulse d. In response to lighting of the light emitting element 1, the output e becomes "0" and the output f becomes "1". When the output f becomes “1”, M
The SM circuit is activated and the pulse setting time of the MSM circuit Q. is extended to 8. From then on, every time the pulse of the output f rises, the output pulse of the MSM circuit is extended to , 6, and so on.
6, returns to "0". In other words, the MSM circuit is a retrigger (RETRIGGER) monostable multipipulator in which the pulse setting time is extended by 1 every time it is triggered by a pulse rising signal, so the pulse setting time of the MSM circuit is QI, but the pulse setting time is When the output f is input to the MSM circuit until the time QI has elapsed, a pulse is again derived for the pulse setting time QI from the input point.

Therefore, the pulse setting time is changed from QI to 81. Further, when the finger is released at time t4, the MSM circuit is triggered by the rising signal of the pulse f input between BI and yl, and the output becomes "0" at time 61 when the pulse setting time QI has elapsed.

Next, when you release your finger at time t4 as shown in Figure 4B, the light emitting element 1 is lit at this time, so the light receiving element 2 is
F, the output e becomes "1" and the output f becomes "0".

Even if the output f becomes "0", the MSM circuit is not affected. Therefore, the level of output b does not change and remains "1")
It is. Therefore, the output c also remains at "0", and the light emitting element 1 also remains lit. In other words, the light emitting element 1 remains lit even if the finger is released. As for the lighting time and the light-off time, if an oscillator PSC with a large duty ratio is used, even if the light emitting element 1 is momentarily turned off, it will not be visually recognized. That is, although the light emitting element 1 turns off at time T, this turning off is not recognized. (0) Regarding the OFF operation of the switch: Insert your finger at the point.

When this finger is inserted, the light emitting element 1 is lit, so the light emission is blocked. Therefore, the output e is “1”
” to “0”, and conversely, the output f changes from “0” to “1”. The MSM circuit is activated by the rising edge of the pulse of the output f, outputting a pulse and becoming “1”. Therefore, the OFF circuit The output b, which was previously “1”, becomes “0”.
Therefore, the Q of the DFF circuit becomes "1". Output b is “0”
” and the output f is “1”, the output c becomes “1” and the light emitting element 1 turns off. Therefore, the output e becomes “1”.
”, and the output f becomes “0′1”. Output f is ``0''
When , the output of the MSM circuit does not change. Therefore, the output b is "0". That is, as a result of this, the operation of the light emitting element 1 is reversed, so that the light-off time T2 becomes longer than the light-on time. Even if the finger is released at time T7, no change in operation occurs since the light emitting element 1 is off at this time. From then on, output e is “1” and output f is “0”.
is connected, and the output g returns to "0" at y2. In addition, Q2 at the output g is the set time by the pulse when the finger is inserted, 82 is the time extended by the rising edge of the pulse 22,
y2 is the time extended by pulse et al. after that,
Since the output f is "0", the pulse of the output g is not extended and returns to "0" at time t8. Now, if you release your finger at time k, that is, when light emitting element 1 is lit, the output e
becomes "1" and the output f becomes "0". In other words, it can be seen that the pulses only change as shown by the dotted line and do not undergo any other changes. Also, when the output b is "1", the output of the NOT circuit NOT is "0", so
Load Z is energized.

As described above, since the present invention can perform ON/OFF control without contact, it is possible to provide an illuminated switch that has a long life, is easy to control, and has a high response speed.

[Brief explanation of the drawing]

Fig. 1 is a sectional view showing an example of the light emitting/receiving part of the side light type switch according to the present invention, Fig. 2 is an electric circuit diagram showing an example of the switch, and Figs. 3 A to G are diagrams for explaining the operation. The pulse waveform diagram and FIGS. 4A and 4B are explanatory diagrams of the operation of the light emitting and receiving section. 1... Light emitting element, 2... Light receiving element, X...
...control circuit, OSC ...oscillator. Figure 1 Figure 2 Figure 4 Figure 3

Claims (1)

[Claims] 1. A light-emitting element, a light-receiving element that operates upon receiving reflected light from the light-emitting element, and a control means for changing the duty ratio of a drive pulse for the light-emitting element according to the light output from the light-receiving element,
An illuminated switch characterized in that the light emitting element lights in pulses with a small duty ratio when turned off, and lights in pulses with a large duty ratio when turned on.