JP4983117B2 - Power switch circuit - Google Patents

Description

The present invention relates to a non-locking type power switch circuit capable of reducing standby current (dark current).

If a thin and small non-locking type switch (for example, a tact switch) can be used for the power switch (power switch) that is a mechanical component, the mounting space on the operation surface can be reduced. Therefore, it is particularly preferable for use with a portable device.

However, such a tact switch cannot be used with a large current for operating the main circuit for small signals. Therefore, for example, a relay for supplying current to the main circuit is provided separately, and this relay and the tact switch are connected via a holding circuit, and the relay is turned on / off by the operation of the tact switch. Therefore, it has been necessary to allow the holding circuit to accept a signal from the tact switch at any time by supplying a standby current even during power-off.

As one method for reducing this standby current, for example, in Patent Document 1, an electronic switch (semiconductor relay) means 3 is provided between the battery Vcc and the power supply means 1 as shown in FIG. In addition to supplying electric power, a switch monitor means 5 is provided to detect that the switch means PS1 is turned off and to input it to the control means 4, and the output from the control means 4 and the output of the switch means PS1 are ORed. It describes what is inputted to the electronic switch means 3 through a circuit.

In this device, when the switch means PS1 is turned on, the electronic switch means 3 is turned on to supply power to the power supply means 1 and operate the main circuit (control means 4). The activated main circuit outputs the ON signal PS2 and holds the ON state of the electronic switch means 3.

On the other hand, when the switch means PS1 is turned off in the on state, the switch monitor means 5 detects that the switch means PS1 is turned off and inputs it to the control means 4. Then, since the control means 4 turns off the ON signal PS2 and turns off the electronic switch means 3, the power supply means 1 is also turned off and the main circuit is also turned off. By doing so, it is described that the standby current to the power supply means 1 at the time of OFF is reduced.

Japanese Patent Laid-Open No. 06-339222

However, in the above, the switch means PS1 of FIG. 7 must be kept on while it is on and kept off while it is off, so it cannot be used for a non-locking type switch. Further, in order to use a non-locking type switch for the above-mentioned switch means PS1, it is considered that a holding circuit and a discrimination circuit for discriminating on / off are necessary. Therefore, the structure becomes complicated and the cost is increased. Further, when the switch means PS1 is on, a current flows through both the PS2 line and the switch monitor means 5 in FIG.

Accordingly, an object of the present invention is to eliminate the standby current of a power switch circuit using a non-locking type switch. Furthermore, it is possible to easily realize a circuit that does not pass the standby current.

In order to solve the above problems, in the present invention, a power supply, a power supply control means for controlling power supply from the power supply to the main circuit unit, and a relay means provided between the power supply and the power supply control means A power switch circuit comprising: a non-locking power switch; switch means for supplying power from the power source to the power control means only when the power switch is closed; and detecting an open / closed state of the power switch. When the power switch is closed in a state where power is not supplied from the power supply to the power supply control means, the power supply control means is powered and operated by the switch means. The power control means is configured so that the closed state of the power switch is not less than a first predetermined time. When it detects that continues, turn on the relay means to allow power from said power source to said power control means is to that adopted the configuration of supplying electric power to the main circuit from the power source.

By adopting such a configuration, the switch means is activated when the non-locking power switch is turned on, so that power can be directly supplied to the power supply control means so as to be activated. In this way, when the non-locking type power switch is operated, the detecting means and the power supply control means (the main circuit is not activated) can be activated to activate the relay means. Then, by operating the relay means, a large current for driving the main circuit can be supplied. At that time, when the power switch is activated, the detection means outputs the activation to the power control means. Therefore, the power control means can determine whether the power switch is on based on the continuation time. The power can be turned on and off with a switch.

At this time, in a state where the relay means is on and the power control means supplies power to the main circuit section from the power supply, the power switch is closed, and the detection means is in the closed state. When it is detected that the power supply has continued for a second predetermined time or more, the power supply control unit can employ a configuration in which the power supply control unit stops supplying power to the main circuit unit and then turns off the relay unit. .

By adopting such a configuration, it is possible to determine whether the non-locking power switch is on or off based on the pressing time. Therefore, for example, the power can be turned on and off without using a latch circuit or the like.

The power switch circuit includes a power source, a power source control unit for controlling power supply from the power source to the main circuit unit, and a relay unit provided between the power source and the power source control unit. A non-locking power switch; and relay control means for turning on the relay means from the power source only when the power switch is closed;
And a detection means for detecting an open / closed state of the power switch and outputting the detected power switch to the power supply control means. When the power switch is in a closed state in a state where power is not supplied from the power supply to the power supply control means, the power supply control means. Is operated by being supplied with power by the relay control means, and the power supply control means keeps the relay means on when it detects that the closed state of the power switch continues for a first predetermined time or more. It is possible to adopt a configuration in which power is supplied from the power source to the power source control means and power is supplied from the power source to the main circuit unit.

By adopting such a configuration, power can be supplied to the power supply control means via the relay means so that it can be activated. In this way, when the non-locking power switch is operated, the detection means and the power supply control means (the main circuit is not activated) can be activated. The activated power supply control means operates the relay means to supply a large current for driving the main circuit.

At this time, in a state where the relay means is on and the power control means supplies power to the main circuit section from the power supply, the power switch is closed, and the detection means is in the closed state. When it is detected that the power supply has continued for a second predetermined time or more, the power supply control unit can employ a configuration in which the power supply control unit stops supplying power to the main circuit unit and then turns off the relay unit. .

By adopting such a configuration, it is possible to determine whether the non-locking power switch is on or off based on the pressing time.

Since the present invention is configured as described above, all the circuits can be turned off by turning off the power switch, and the standby current of the circuit can be brought close to zero.

Hereinafter, embodiments of the present invention will be described with reference to the drawings.

[Embodiment 1]
The power switch circuit of this embodiment is used for an electronic device such as a portable wireless communication device and supplies power from a battery Vcc to a display as shown in FIG.

As shown in FIG. 1, this power switch circuit includes a non-locking power switch 10, a relay means 11, a detection circuit 12, a microprocessor 13, a regulator 14, a switch 16, and a battery (power source) Vcc. A first power line 17 and a second power line 18 are provided in parallel between the battery Vcc and the regulator 14. That is, the relay means 11 is provided in the first power supply line 17, and the power switch 10, the detection circuit 12, and the switch means 16 are provided in the second power supply line 18.

The non-locking power switch 10 is in an ON state with the contact closed only while the button is pressed, and is turned OFF with the contact open when the button pressing force is removed. For example, a tact switch or the like is provided in the casing of the portable wireless device. In this case, a tact switch is used as the non-locking power switch 10, but the tact switch is not limited to this. Any switch can be used.

Here, the relay means 11 uses a semiconductor switch relay, and a control terminal is connected to the microprocessor 13 so that on / off control can be performed. Here, although the semiconductor switch relay is used for the relay means 11, it is not limited to this. In addition to this, for example, a small mechanical relay or a reed relay can be used.

The detection circuit 12 detects the open / close state of the power switch 10. Specifically, the detection circuit 12 detects the potential of the second power supply line 18 provided with the power switch 10 and outputs it to the microprocessor 13.

The microprocessor 13 is provided as power supply control means, and is supplied with power from the first power supply line 17 or the second power supply line 18 via the regulator 14. The microprocessor 13 has various inputs and outputs such as a built-in ROM, timer means, and interrupt, and further includes a reset circuit to execute a predetermined program in the built-in ROM when the power is turned on. Control. It also manages the power supply to the main circuits such as the display of the portable radio.

The regulator 14 is a stabilized power supply for the microprocessor. Here, the regulator 14 is arranged between the connection point of the parallel circuit of the relay means 11 and the power switch 10 and the microprocessor 13 as shown in FIG. Electric power can be supplied.

The switch means 16 is turned on and off in conjunction with the opening and closing of the power switch 10, and is provided for supplying power from the battery Vcc to the microprocessor 13 only when the power switch 10 is closed. In this embodiment, the switch means 16 is a microprocessor that sandwiches the detection circuit 12 on the second power supply line 18 so that the potential of the second power supply line 18 changes in conjunction with the opening and closing of the power switch 10. It arrange | positions so that it may be located in the 13th side. In this way, when the power switch 10 is off, no voltage is applied to the detection circuit 12 via the first power supply line 17 so that erroneous detection is prevented. Therefore, a semiconductor switch such as a diode can be used for the switch means 16.

The battery Vcc is a built-in battery of a portable radio device.

This embodiment is configured as described above, and the on / off operation of the power switch of the present application will be described based on the flowcharts of FIGS. 2 and 3 and the operation explanatory diagrams of FIGS.

FIG. 4A shows a state where the power supply of the electronic device itself is off. In this state, since the first power supply line 17 and the second power supply line 18 are both open, power is not supplied from the battery Vcc to the microprocessor 13. In this state, as shown in FIG. 4B, when the power switch 10 is pressed, the switch means 16 is turned on in conjunction with the second power supply line 18. Therefore, power is supplied from the battery Vcc to the microprocessor 13 via the regulator 14, and the microprocessor 13 is activated (processing S100, hereinafter “processing” is omitted).

Next, when the power switch 10 is pressed, the potential of the second power supply line 18 becomes a high potential. The detection circuit 12 recognizes that the power switch 10 is in the closed state (ON state) when the second power supply line 18 becomes 1 V or higher, and outputs the result to the microprocessor 13. In a state where the power switch 10 is continuously pressed, the second power supply line 18 is closed (the switch 16 is turned on) (S110). Then, the microprocessor 13 measures the duration of the closed state of the power switch 10 by the output from the detection circuit 12. At this time, the microprocessor 13 does not perform a normal power supply operation such as display on the display (LCD or LED) 20, and starts measuring the duration of the detection output input from the detection circuit 12 (S120).

When the microprocessor 13 recognizes that the duration of the closed state of the power switch 10 has reached 300 ms or more, as shown in FIG. 4C, the microprocessor 13 sends a control signal PON for turning on the relay unit 11. Output.

When the relay unit 11 is turned on, even if the power switch 10 is released (without pressing), the first power supply line 17 is always turned on, and power is supplied from the battery Vcc (S140). When power is supplied through the relay means 11 in this way, the microprocessor 13 performs a normal operation such as display on the display 20, for example, as shown in FIG. (S150).

On the other hand, when turning off the power, when the power switch 10 is pressed (turned on) as shown in FIG. 5B during the operation as shown in FIG. 5A, the power switch 10 is pressed. The detection means 12 detects this and outputs a detection output to the microprocessor 13. When the detection output is input, the microprocessor 13 starts measuring time. When the time exceeds 1000 ms (S210) and the voltage level exceeds 1V (according to the measurement described above), the control signal PON to the relay means 11 is turned off as shown in FIG. The relay means 11 is turned off. At the same time, the microprocessor 13 ends a normal operation such as display on the display 20, for example. In this state, power is still supplied to the detection circuit 12 and the microcomputer 13 (the switch 16 is on) via the power switch 10, and the power switch 10 is released and turned off as shown in FIG. Then, the detection circuit 12 and the microprocessor 13 are completely separated from the battery Vcc, the first power supply line 17 and the second power supply line 18 are turned off (S220), and no standby current flows. Therefore, no standby current flows while the power is off.

In this way, the power supply can be turned on and off by starting the circuit without passing a standby current with a non-locking switch with a simple circuit. For this reason, it is not necessary to constantly supply power to the microprocessor 13, and for example, when used in a portable device, battery consumption can be suppressed. Further, by determining whether the non-locking switch is on or off from the duration of the switch, for example, it is possible to easily determine on / off without using a latch circuit or the like.

[Embodiment 2]
In this embodiment, as shown in FIG. 6, the switch means operates the relay means 11 in conjunction with the opening and closing of the power switch 10 to supply power to the microprocessor 13.

That is, as shown in FIG. 6, the power switch 10 is connected to the base of the PNP transistor TR1 of the detection circuit 12, and the collector of the transistor TR1 is input to the microcomputer 13. Thus, when the switch 10 is pressed, the detection output is input to the microcomputer 13. The transistor TR1 forms the relay control means 21 with the transistor TR2, and is connected to the control terminal of the relay means 11 through an OR circuit. Therefore, when the power switch 10 is pressed, the relay means 11 is activated to supply power to the microprocessor 13 from the battery Vcc. When power is supplied, the microprocessor 13 is activated and starts measuring the duration of the detection output. When the time reaches a predetermined time (300 ms in the embodiment), the microprocessor 13 outputs a control signal to the relay means 11 via the OR circuit and keeps the relay means 11 in the ON state. At this time, the transistor TR3 is for inverting the control signal so as to match the polarities. As a result, the on-normal state can be maintained even when the power switch 10 is released.

On the other hand, when the power is turned off, the power switch 10 is pressed (turned on) during the operation of the main body. Then, the PNP transistor TR1 of the detection means 12 is turned on and a detection output is output to the microprocessor 13. The microprocessor 13 starts timing when the detection output is input. When the time t2 exceeds a predetermined time (1000 ms in the embodiment), the control signal to the relay unit 11 is turned off. At the same time, the microprocessor 13 ends a normal operation such as display on the display 20, for example. At this time, the collector means 11 receives the collector output of the PNP transistor TR1 of the detecting means 12 through the OR circuit, and keeps the ON state and supplies power to the microcomputer 13. Here, when the power switch 10 is released, the PNP transistor TR1 of the detection means 12 is turned off, the output input to the OR circuit is also turned off, and the relay means 11 is turned off. Therefore, the microprocessor 13 is completely separated from the battery Vcc, and no standby current flows. Therefore, no standby current flows while the power is off.

As described above, it is possible to prevent the standby current from flowing without always supplying power to the microprocessor 13, but at this time, the circuit can be activated without supplying the supply current to the power switch 10. Therefore, for example, a failure of the power switch 10 such as a short circuit or sticking can be reduced, and a highly reliable switch can be configured, and the life of the switch 10 can be extended.

According to the present invention, the power supply can be turned on / off with a simple circuit without passing standby current with a non-locking switch. Therefore, for example, it is most suitable for use in electronic devices that require low power consumption, such as portable information terminals and music and video players.

Block diagram of Embodiment 1 Flowchart of the first embodiment Flowchart of the first embodiment Action explanatory drawing of Embodiment 1 Action explanatory drawing of Embodiment 1 Circuit diagram of Embodiment 2 Block diagram of conventional example

Explanation of symbols

DESCRIPTION OF SYMBOLS 10 Power switch 11 Relay means 12 Detection circuit 13 Microprocessor 21 Relay control means Vcc Battery

Claims (2)

A power switch circuit comprising a power supply, a power supply control means for controlling power supply from the power supply to the main circuit unit, and a relay means provided between the power supply and the power supply control means,
Non-locking power switch,
Switch means for supplying power from the power supply to the power supply control means only when the power switch is closed;
Detecting means for detecting an open / closed state of the power switch and outputting to the power control means;
When the power switch is closed in a state where power is not supplied from the power source to the power control means, the power control means is powered and operated by the switch means,
When detecting that the closed state of the power switch continues for a first predetermined time or more, the power control means controls the relay means to be kept on, and controls the power control means from the power source. Power supply to the main circuit unit from the power source ,
On the other hand, in the state where the relay means is on and the power control means supplies power to the main circuit section from the power source.
When the power switch is in a closed state and the detection unit detects that the closed state continues for a second predetermined time or more, the power control unit stops supplying power to the main circuit unit. Thereafter, the power switch circuit is characterized in that the relay means is turned off . A power switch circuit comprising a power supply, a power supply control means for controlling power supply from the power supply to the main circuit unit, and a relay means provided between the power supply and the power supply control means,
Non-locking power switch,
Relay control means for turning on the relay means from the power source only when the power switch is closed;
Detecting means for detecting an open / closed state of the power switch and outputting to the power control means;
When the power switch is in a closed state with no power being supplied from the power source to the power control means, the power control means is powered and operated by the relay control means,
When the power supply control means detects that the closed state of the power switch continues for a first predetermined time or more, it controls to keep the relay means on,
Enables power supply from the power supply to the power supply control means, supplies power to the main circuit section from the power supply,
On the other hand, in the state where the relay means is on and the power control means supplies power to the main circuit section from the power source.
When detecting that the power switch is in a closed state and the closed state of the detection means continues for a second predetermined time or more,
The power supply control circuit is characterized in that the power supply control means turns off the relay means after stopping the supply of power to the main circuit section .

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