JPH03154880A - Method and device for detecting coming-off of power source plug - Google Patents

Abstract

PURPOSE:To detect the power source plug coming off a power source outlet by monitoring the impedance obtained by viewing the power source plug side from the power source line connected to the power source plug. CONSTITUTION:Many AC outlets are connected to interior wiring and various electric equipments are connected in parallel through those outlets. Then the impedance when exterior wiring is viewed from the interior wiring is equal to the secondary-side impedance of a pole mounted transformer, so the impedance is extremely small. Therefore, when the AC plug 1 of an equipment is connected correctly to an AC outlet, the impedance when the side of the plug 1 is viewed from power lines 2a and 2b in the equipment is the sum of the power input impedance of all the equipments connected to the interior wiring and the impedance of the exterior facilities regardless of power feeding and a power failure and extremely small, but when the plug 1 is pulled out of the outlet, the impedance obtained by viewing the side of the plug 1 becomes extremely large. The variation in impedance like this is used to detect the coming-off of the plug.

Description

DETAILED DESCRIPTION OF THE INVENTION (Field of Industrial Application) The present invention relates to a method and apparatus for detecting disconnection of a power plug from a power source, which can detect disconnection of a power plug of an electrical device from a power outlet, distinguishing it from a power outage.

(Prior Art) Electrical devices used in homes are usually configured to receive power from an AC outlet via an AC plug attached to the device. Some electrical devices are useless unless the AC plug is plugged into an outlet at all times.

For example, a gas leak alarm can detect an unexpected gas leak and issue an alarm by constantly supplying power and keeping it in an active state. Alarm A due to carelessness or intentionality
If you leave the C plug unplugged from the outlet, it will not work in the event of a gas leak.

To avoid this situation, a microswitch is attached to the front of the AC plug, and when the plug is inserted into the outlet, the switch is pressed, and when the plug is removed from the outlet, the switch is reset. Devices that generate contact signals are known. According to this method, disconnection of the AC plug can be detected as distinct from a power outage by detecting the contact signal of the microswitch with a detection circuit.

(Problem to be Solved by the Invention) In the conventional technology of attaching a microswitch to a power plug to detect disconnection of the plug, the contact signal of the microswitch is guided to a detection circuit in an electrical device such as a gas leak alarm. A separate cable is required in addition to the power cord. Therefore, wiring work for this contact signal extraction cable is required, and the appearance of the wiring is also poor.

In addition, there is a possibility that the microswitch will be activated even if the power plug is not removed from the outlet and is inserted slightly loosely, which poses a problem in terms of reliability.

An object of the present invention is to solve these problems and provide a method and device for detecting disconnection of a power plug, which can distinguish disconnection of a power plug from an outlet from a power outage without adding a switch or the like to the power plug. shall be.

(Means for Solving the Problems) The power plug disconnection detection method according to the present invention monitors the impedance of the power plug when viewed from the power line connected to the power plug, thereby removing the power plug from the power outlet. It is designed to detect omissions.

In addition, the power plug disconnection detection device according to the present invention includes a first switch element that is inserted into the power line and turns on when current flows through the power line, and an impedance that changes depending on the presence or absence of current flowing through the power line. A voltage dividing circuit that includes an impedance element that changes the voltage as a voltage dividing element and divides the DC voltage, and is connected between the power line between the power plug and the first switch element and the voltage dividing point of the voltage dividing circuit. and a second switch element that is turned on when no current flows through the power line, and means for detecting disconnection of the power plug from the power outlet based on the output voltage of the voltage dividing circuit. do.

(Function) Generally, the impedance seen from indoor wiring to outdoor wiring is small, and multiple devices are connected to indoor wiring through power outlets. For this reason, if you look at the impedance seen from the power line inside the electrical device connected to the power outlet to the power plug side, the value is extremely small when the power is on and when the plug does not come out and there is a power outage, but when the power plug is If it is unplugged from the outlet, it will become extremely loud. Therefore, by monitoring this impedance, disconnection of the power plug can be detected as distinct from a power outage.

Further, in the device of the present invention, the first switch element is in the OFF state and the second switch element is in the ON state at the time of a power outage and when the power supply plug is unplugged.

Here, if the power plug is unplugged during a power outage,
Because the impedance when looking from the power line to the power outlet is small, for example, the divided voltage of a voltage divider circuit is small, but when the power plug is unplugged, the impedance is large, so for example, the output voltage of the voltage divider circuit is high. Become. Therefore, it is possible to detect whether the power plug is disconnected from the outlet based on the output voltage of this voltage dividing circuit.

(Example) Hereinafter, the present invention will be described in detail with reference to the drawings. FIG. 1 is a circuit diagram showing the configuration of a power plug disconnection detection device according to an embodiment of the present invention.

In Figure 1, the AC plug 1 has a pair of power lines'
;la and 2b are connected, and a fuse 3 is inserted into one power supply input 2a. In addition, the power line 2a,
A surge absorbing element 4, a resistor 5 and a relay 6 are connected between 2b.
A series circuit of excitation coils 7 is connected.

Make contacts 8a and 8b of the relay 6, which are first switch elements, are inserted into the power supply lines 2a and 2b, respectively. A load device 12 (for example, a gas leak alarm) is connected to the power lines 2a and 2b after the contacts 8a and 8b via a transformer 10 and a rectifier circuit 11 in this order.

A capacitor 14 is connected to the output side of the rectifier circuit 11 via a diode 13. The capacitor 14 is a DC power supply for the plug-out detection device, and is an electrolytic capacitor.

On the other hand, a relay 6, which is a second switch element, is connected to the power lines 2a and 2b on the side of the power plug 1 from the contacts 8a and 8b.
One end of each of the break contacts 9a and 9b are connected to each other. Contact point 9a.

The other ends of 9b are connected to both ends of the surge absorbing element 15, and are also connected to the cathode and anode sides of backflow prevention diodes 18 and 19 via resistors 16 and 17, respectively. A surge absorption element 20, a constant voltage diode 21, and a light receiving element portion of a first photocoupler 22 are connected in parallel between the anode side of the diode 18 and the cathode side of the diode 19. The light emitting element portion of the photocoupler 22 is connected to the output end of the rectifier circuit 11 via a resistor 23. Therefore, the light receiving element portion of the photocoupler 22 acts as an impedance element whose impedance changes depending on the presence or absence of current flowing through the power supply lines 2a and 2b (that is, the presence or absence of rectified output of the rectifier circuit 11).

Further, a light receiving element portion of the photocoupler 22 is connected to a connection point between the diode 13 and the capacitor 14 via a resistor 24. Light receiving element part of photo coupler 22 and resistor 2
4 and the power lines 2a, 2b when looking at the AC plug 1 side, constitute a voltage dividing circuit 25 that divides the terminal voltage of the capacitor 14, and the voltage dividing point is connected to the resistor 2.
6 to the base of the transistor 27. The collector of this transistor 27 is connected to the connection point between the diode 13 and the capacitor 14 via the light emitting element portion of the second photocoupler 28 and two current limiting resistors, and the emitter is grounded. The light receiving element portion of the photocoupler 28 is an output terminal 30a.

30b.

Next, the operation of the power plug disconnection detection device of this embodiment will be explained.

In a typical home, many AC outlets are connected to indoor wiring, as shown in Figure 2, and various electrical devices are connected in parallel through these outlets, and it is possible for any one of the devices to be operating at any time. many. Additionally, as shown in the figure, power is normally supplied to each home through a wattmeter or a safety device (breaker), and the outside of the wattmeter is connected to a pole transformer owned by the power company. There is.

The impedance seen from the indoor wiring to the outdoor wiring side is extremely small because it is the secondary impedance of the pole transformer.

Therefore, if the AC plug 1 of the device is correctly inserted into the AC outlet, regardless of whether the power is on or during a power outage,
Power line 2a inside the device.

The impedance when looking at the plug 1 side from 2b is a parallel composite impedance of the power input impedance of all devices connected to the indoor wiring and the impedance of the outdoor facility, and is extremely small.

On the other hand, when the plug 1 is removed from the outlet, the impedance seen from the power lines 2a and 2b toward the plug 1 becomes extremely large. The device shown in FIG. 1 detects that the plug 1 has been removed from the outlet by utilizing such impedance changes.

The subsection shows the state of each part in Fig. 1 when electricity is on, when there is a power outage, and when the plug is removed.

In addition, 2 indicates the magnitude of the impedance when looking at the AC plug 1 side from the power lines 2a and 2b, RYM is the make contact 8 a, 8 b s RYB is the break contact state, C is the charging/discharging state of the capacitor 14, PCI is the first
, Q is the state of the transistor 27, and PO2 is the state of the second photocoupler 28.
The states of the light-receiving element sections are shown respectively.

When the AC plug 1 is inserted into the AC outlet and is energized, the coil 7 of the relay 6 is energized, so the make contact 8g.

8b is on, and break contacts 9a and 9b are off. Therefore, power is supplied to the load device 12 via the transformer 10 and the rectifier circuit 11.

Further, at this time, the capacitor 14 is in a charging state.

On the other hand, in the first photocoupler 22, since the light emitting element section is energized via the resistor 23, the light receiving element section Pct is in an on state. Therefore, since the output voltage of the voltage dividing circuit 25, that is, the base potential of the transistor 27 becomes a low potential, the transistor 27 is turned off, and the light receiving element portion PC2 of the second photocoupler 28 is also turned off.
The output terminals 30a and 30b are in an open state.

During a power outage If a power outage occurs while the AC plug 1 is inserted into the AC outlet, the coil 7 of the relay 6 will not be energized and the contact 8a
, 8b is off, contact 9a.

9b is turned on. In this case, the first photocoupler 2
The light receiving element portion PC+ of No. 2 is in an off state and has a high impedance, and a contact point 9a is connected thereto.

9b, the impedance 2 that enters in parallel through the resistors 16 and 17 and the diodes 18 and 19 is extremely small.
The output voltage of the voltage dividing circuit 25 is still low, the transistor 27 is in an off state, the light receiving element part PC2 of the second photocoupler 28 is also in an off state, and the output terminals 30a and 30b
becomes open. That is, the output terminal 30a.

The state of 30b is when the power is on.

When the plug is removed When the AC plug 1 is removed from the AC outlet, the coil 7 of the relay 6 is not energized and the contacts 8a and 8 are
b is off, and contacts 9a and 9b are on. Further, the light receiving element part PCs of the first photocoupler 22 is in an off state and has a high impedance, and the contact 9 is connected to this light receiving element part.
The impedance 2 in parallel via a +9b, resistor 16.17 and diode 18°19 also becomes extremely large. That is, the transformer 10 is connected by the contacts 8a and 8b.
Since the primary side of the plug 1 is disconnected, the impedance 2 seen from the power supply lines 2a and 2b toward the plug 1 is mostly the series combined resistance of the resistor 5 and the coil 7 of the relay 6.

Therefore, the output voltage of the voltage dividing circuit 25, that is, the base potential of the transistor 27 becomes large, and the transistor 27 is turned on, and the light receiving element portion PC2 of the second photocoupler 28 is turned on.
is also turned on.

At this time, the output terminals 30a and 30b are short-circuited,
The state will be different from when the power is on and when there is a power outage. This state continues until the charge in the capacitor 14 is discharged by the output voltage of the voltage dividing circuit 25 to such an extent that the transistor 27 cannot maintain the on state.

In this way, disconnection of the AC plug 1 from the outlet can be detected as a change in the output signals from the output terminals 30a and 30b. Therefore, using this output signal, the AC
When the plug 1 is removed, for example, a gas leak alarm shutoff system can be activated to generate an alarm, and at the same time, the shutoff valve can be shut off to stop the gas supply.

Note that the present invention is not limited to the above embodiments, and can be implemented with various modifications. For example, instead of using the capacitor 14, a dry battery or other battery may be used as the DC power source of the unplugged detection device.

(Effects of the Invention) As described above, according to the present invention, the disconnection of the power plug from the outlet can be detected as distinguished from a power outage by using the impedance seen from the power line of the device toward the power plug side.

Additionally, compared to conventional technology that adds a switch or the like to the power plug, there is no need for wiring between the plug and the detection device.
Moreover, highly reliable detection results can be obtained without being affected by slight changes in the state of insertion of the power plug into the outlet.

[Brief explanation of the drawing]

FIG. 1 is a circuit configuration diagram of a power plug disconnection detection device according to an embodiment of the present invention, and FIG. 2 is a diagram showing a power supply system in a general household for explaining the present invention in detail. 1...AC plug, 2a, 2b...power line, 3
...Fuse, 4,15.20...Surge absorption element, 6...Relay 7...Relay excitation coil, 8a
, 8b...Make contact (first switch element) 9
a, 9b... break contact (second switch element),
10...Transformer, 11...Rectifier circuit, 13.18
．． 19... Backflow prevention diode, 21... Constant voltage diode, 22.28... Photocoupler, 23...
- Current limiting resistor, 24... Voltage dividing resistor, 25... Voltage dividing circuit, 26... Bias resistor, 27... Transistor, 29... Current limiting resistor, 30a, 30b... Output terminal .

Claims (2)

[Claims] (1) A method for detecting disconnection of a power plug, which is characterized in that disconnection of a power plug from a power outlet is detected by monitoring the impedance seen from the power line connected to the power plug toward the power plug side. (2) Insert into the power line connected to the power plug,
A voltage dividing element that divides a DC voltage, including a first switching element that is turned on when current flows through the power supply line, and an impedance element whose impedance changes depending on the presence or absence of current flowing through the power supply line. a first switch connected between a power line between the power plug and the first switch element and a voltage dividing point of the voltage dividing circuit, and which is in an on state when no current flows through the power line; 2. A power plug disconnection detection device, comprising: a second switch element; and means for detecting disconnection of the power plug from the power outlet based on the output voltage of the voltage dividing circuit.