KR20220112920A - Standby Power Shutoff Socket Having Capacitor for Selecting Standby Mode - Google Patents

Abstract

The present invention relates to a standby power blocking outlet which detects the time when power supplied to a load drops below the standard and determines that the load is not being used, and allows the output of an outlet to be removed. The standby power blocking outlet comprising a condenser for conversion to a constant mode of the present invention comprises: a power input terminal; outlet output terminals connected in parallel to the power input terminal; a power supply device connected to the power input terminal to convert AC power into DC power and supply the converted power; a constant conversion switch connected between a first power input terminal of the power input terminal and the power supply device; a relay connected between the first power input terminal and a first outlet output terminal of the outlet output terminal connected to the first power input terminal; a current sensor unit sensing a load current value between the first power input terminal and the first outlet output terminal; and a relay driving unit using supply power supplied from the power supply device, performing a standby power blocking mode for turning on/off a contact of the relay according to the current value sensed by the current sensor unit when the constant conversion switch is turned on, and turning on a contact of the relay to perform a constant mode when the constant conversion switch is turned off. In addition, the relay driving unit includes a condenser for conversion to a constant mode charging energy during the standby power blocking mode, discharging the charged energy when changing to the constant mode, and driving the relay. Accordingly, the standby power blocking outlet which does not consume standby power itself is provided.

Description

Standby Power Shutoff Socket Having Capacitor for Selecting Standby Mode

The present invention relates to a standby power blocking outlet that detects when the power supplied to a load falls below a standard, determines that the load is not in use, and removes the outlet output. It relates to a standby power cut-off outlet configured to minimize power consumption when a regular changeover switch for selectively using a mode and a regular mode for supplying power at all times is operated.

Most of the apartments currently being built provide tenants with a standby power blocking outlet that enables remote on/off and monitoring as a standard. It includes a function to automatically cut off the power supplied to home appliances by determining whether there is

In the conventional standby power blocking outlet, power supply is automatically cut off when the home appliance is not in use, but power consumption of the outlet itself, such as standby power state monitoring, occurs.

In addition, if you do not use the standby power blocking outlet function and want to use it as an outlet for general constant power supply, you must implement to enable constant power supply through physical switching by the user. In order to design to be durable, it was necessary to consider the physical space and mechanical mechanism, and accordingly, the problem of increase in design cost and cost occurred.

In order to solve this problem, the present applicant has invented a standby power blocking outlet that does not consume its own standby power as a configuration for supplying power at all times.

Registered Patent No. 10-0909598 (2009.07.24. Announcement)

It is an object of the present invention to provide a standby power blocking outlet that does not consume its own standby power as a configuration for constant power supply. Other objects of the present invention can all be achieved by the detailed description of the present invention described with reference to the accompanying drawings.

In order to achieve the above object, the standby power cutoff outlet including a capacitor for constant mode conversion of the present invention includes a power input terminal; an outlet output terminal connected in parallel to the power input terminal; a power supply connected to the power input terminal to convert AC power into DC power and supply; a regular changeover switch connected between a first power input terminal of the power input terminal and the power supply device; a relay connected between the first power input terminal and a first outlet output terminal of the outlet output terminal connected thereto; a current sensor unit for detecting a load current value between the first power input terminal and the first outlet output terminal; And using the power supplied from the power supply device, when the regular changeover switch is on, performing a standby power cut-off mode to turn on/off the contact point of the relay according to the current value sensed by the current sensor unit, and , when the regular changeover switch is turned off, a relay driver that turns on the contact of the relay to perform a regular mode; and, the relay driver charges energy while in standby power cut-off mode and then changes to the regular mode. and a capacitor for constant mode conversion for driving the relay while discharging the charged energy.

In addition, in the present invention, the relay includes a permanent magnet so that an on state is maintained even when a current is opened, a first coil that turns on the contact when a current flows, and a second coil that turns off the contact when a current flows It is a latch relay comprising a, and the first node between the first coil and the second coil in the relay driving unit is connected to the supply power supplied from the power supply device, and is located on the opposite side of the first coil in the relay driving unit A second node and a third node on the opposite side of the second coil include a current intermittent circuit for selectively intercepting the flow of current flowing from the first node to the ground terminal by the supply power, and the constant mode switching The capacitor for use is connected in parallel to the first node to charge energy by the supply power.

In addition, in the present invention, the current control circuit includes a drain on the first coil side between the second node and a ground terminal, a source on the ground terminal side, a MOSFET with a gate connected on the first node side, and a gate side of the MOSFET connected a first transistor circuit including a front end transistor, a back end transistor coupled to a rear end of the front end transistor and configured to receive a relay-on signal through a base; and a second transistor circuit coupled between the third node and a ground terminal and configured to receive a relay-off signal to a base, wherein the front-end transistor includes a gate and a first node of the MOSFET at a collector, and the rear-end at a base The collector of the transistor may be connected.

Also, in the present invention, a protection diode for preventing back electromotive force may be connected between the first node and the second node and between the first node and the third node.

In addition, in the present invention, a diode is further connected between the first node and the power supply of the power supply so that the voltage charged in the constant mode conversion capacitor is maintained even when the supply power is lowered, and the A Zener diode connected between the collector terminal of the rear-end transistor and the supply power to turn off the front-end transistor when the supply power is lowered to a Zener voltage or less may be further connected.

According to the standby power cutoff outlet including the condenser for constant mode conversion of the present invention as described above, the flow of current is configured to bypass the regular changeover switch when the regular mode is switched, thereby changing the purpose of the regular changeover switch to the standby power sensing function of the outlet and By using it only for power supply of the power supply that controls the relay driving unit, the load applied to the regular changeover switch can be minimized to achieve physical miniaturization.

1 is a circuit connection structure diagram of a standby power blocking outlet using a latch relay according to an embodiment of the present invention;
2 is a circuit block diagram of a relay-off operation in a standby power cutoff mode of a standby power cutoff outlet including a capacitor for constant mode conversion according to an improved embodiment of the present invention;
Figure 3 is a circuit configuration diagram during the relay-on operation in the standby power cutoff mode of the standby power cutoff outlet including a capacitor for constant mode switching according to an improved embodiment of the present invention; and
4 is a circuit configuration diagram in a normal mode of a standby power cutoff outlet including a capacitor for normal mode switching according to an improved embodiment of the present invention.

Hereinafter, preferred embodiments of the present invention will be described in detail with reference to the accompanying drawings. The terms or words used in the present specification and claims are not limited and interpreted in a conventional or dictionary meaning, but should be interpreted as meanings and concepts consistent with the technical matters of the present invention.

1 is a circuit connection structure diagram of a standby power blocking outlet using a latch relay according to an embodiment of the present invention. According to FIG. 1, the standby power cut-off outlet detects the current supplied to the load connected to the outlet output terminal 20 from the current sensor unit 60 when the home appliance (load) is not in use, and relays when the current is less than or equal to the reference value. (50) is used to cut off the power supplied to the home appliance (load).

Whereas general relays have a simple structure where the contacts are attached when current flows through the coil of the relay and the contacts drop when no current flows, the latch relay uses a permanent magnet to fix the contacts in the applied direction when current is applied for more than 50ms. It is a relay with a structure in which the contact remains attached even if the current is cut off in the coil.

Referring to the drawing, in the standby power cut-off mode, terminal 2 and terminal 3 of the regular switch 40 are connected, the power input terminal 10 is directly connected to the power supply device 30, and terminals 1 and 2 are opened. It is configured such that power is supplied to the load only through the relay 50 .

In this standby power cut-off mode, as shown in the figure, a High signal is applied to the base of the transistor Q1 (73) (application of a relay-off signal), so that Q1 is conducted, and the second coil from the 7th node to the 1st node of the relay 50 A current flows along (56), and the contact (52) of the relay is dropped, and the power of the load is cut off. And when a high signal is applied to the base of the transistor Q2 (71) (application of a relay-on signal) and Q2 conducts, a current flows from the 7th node to the 6th node along the first coil 55 along the first coil 55, at this time the relay contact point (52) is attached so that power can be supplied to the load.

In addition, when terminals 1 and 2 of the regular changeover switch 40 are short-circuited and terminals 2 and 3 are opened, the power input terminal 10 and the outlet output terminal 20 are connected in parallel as they are, so whether the load is used Regardless of the condition, the power is always supplied.

However, since the regular changeover switch 40 is directly connected between the power input terminal 10 and the outlet output terminal 20, it must be designed to handle a current of 16A or more, which is the maximum allowable capacity of a general load. The physical size of the components constituting the device must be increased, and therefore, more space is required for the entire structure of the constant change switch, and secondary problems such as heat generation due to large currents also occur.

Figure 2 is a circuit configuration diagram during the relay-off operation in the standby power cutoff mode of the standby power cutoff outlet including a capacitor for constant mode switching according to an improved embodiment of the present invention, Figure 3 is an improved embodiment of the present invention It is a circuit diagram of a relay-on operation in a standby power cutoff mode of a standby power cutoff outlet including a capacitor for constant mode conversion according to an embodiment, and FIG. 4 is a regular mode according to an improved embodiment of the present invention. It is a circuit configuration diagram in the normal mode of the standby power blocking outlet including the conversion capacitor. A standby power cut-off outlet including a condenser for constant mode conversion according to an improved embodiment of the present invention will be described with reference to FIGS. 2 to 3 .

Referring to the drawings, the standby power cut-off outlet including the condenser for constant mode switching of the present invention is a power input terminal 10 , an outlet output terminal 20 , a power supply device 30 , a regular changeover switch 40 , a relay 50 , a current sensor unit 60 , and a relay driving unit 100 .

The outlet output terminal 20 is connected in parallel to the power input terminal 10 and is a connection element for accommodating a plug of a load, and is always connected to one of the power input terminals, and is connected to the other terminal. It is configured to be turned on/off as necessary for operation in the standby power cut-off mode.

The power supply device 30 is connected to the power input terminal 10 to convert AC power into DC power and supply it to a circuit element for performing a standby power blocking function. In general, a DC voltage of 5V to 12V is generated and supplied.

The regular changeover switch 40 is connected between the first power input terminal 12 of the power input terminal 10 and the power supply device 30 to turn on/off the power supply to the power supply device 30 . It is configured, and when it is on, DC power for operation in the standby power cut-off mode is generated by the power supply device 30 and supplied to the relay driving unit 100 .

The relay 50 is connected between the first outlet output terminal 22 of the outlet output terminal 20 connected to the first power input terminal 12 to turn on/off the power supply to the load. .

The current sensor unit 60 detects a load current value between the first power input terminal 12 and the first outlet output terminal 22 to provide a criterion for determining whether to cut off standby power in the standby power cutoff mode do.

The relay driving unit 100 uses the power supply 32 supplied from the power supply device 30, and when the constant changeover switch 40 is turned on, the current value detected by the current sensor unit 60 is Accordingly, the standby power cut-off mode is performed to turn on/off the contact 52 of the relay 50, and when the regular changeover switch 40 is turned off, the constant mode is performed by turning on the contact 52 of the relay. It is a circuit element composed of a combination of active and passive elements.

In addition, the relay driving unit 100 is charging the energy while in the standby power cut-off mode and discharging the charged energy when the normal mode is changed to the normal mode conversion capacitor 110 for driving the relay 50 . ) is further included.

Therefore, since the regular mode is achieved by operating the relay 50 by using the energy of the capacitor 110 for constant mode conversion, the regular changeover switch 40 is opened in the regular mode and any power through the regular changeover switch 40 is Since it is not consumed, the regular changeover switch 40 can be miniaturized, so a switch for a large current of 16A or more is not used, for example, a switch for a medium current of 2A or more required for switching with the power supply device 30 can be selected.

In addition, in the embodiment of the present invention, the relay 50 includes a permanent magnet, so a contact 52 that maintains an on state even when a current is opened, and a first coil 55 that turns on the contact 52 when a current flows ) and a second coil 56 that turns off the contact 52 when a current flows, and the first coil 55 and the second coil 56 in the relay driving unit 100 ) between the first node (No. 7 node) is connected to the power supply 32 supplied from the power supply device 30 , and the first node located on the opposite side of the first coil 55 in the relay driving unit 100 . In the second node (node 6) and the third node (node 1) on the opposite side of the second coil 56, the flow of current flowing from the first node to the ground terminal by the power supply 32 is selectively selected. It includes a current intermittent circuit (C) for intermittent intermittent mode, and the capacitor 110 for constant mode switching is connected in parallel to the first node and can be configured to charge energy by the power supply 32 .

Therefore, according to the detection signal of the current sensor unit 60 by the current control circuit (C) driven by the power supply 32 in the standby power mode, any one of the first coil 55 and the second coil 56 While the contact 52 is turned on/off by selectively controlling the current with the coil, the constant mode conversion capacitor 110 is charged with energy, and the mode is switched when the constant mode changeover switch 40 is switched to the regular mode. The continuous mode connection by the relay 50 is achieved by turning on the contact 52 by allowing the current to flow to the first coil 55 by the energy of the capacitor 110 for use.

In addition, in the present invention, the current control circuit (C) is composed of a first transistor circuit (120, 130, 140) and a second transistor circuit 150, the first transistor circuit is the second node (node 6) ) and the ground terminal, the drain on the first coil 55 side, the source on the ground terminal side, and the gate on the first node (node 7) side of the MOSFET 120 , on the gate side of the MOSFET 120 . a front-end transistor 130 connected thereto, and a back-end transistor 140 connected to a rear end of the front-end transistor 130 and configured to receive a relay-on signal through a base, wherein the second transistor circuit 150 is the third node It is connected between (Node 1) and the ground terminal and is configured to receive a relay-off signal to the base.

Also, in the front-end transistor 130 , the gate and the first node (node 7) of the MOSFET 120 may be connected to a collector, and the collector of the rear-end transistor 140 may be connected to the base.

Also, as shown, in the present invention, protection diodes D1 and D2 for preventing back electromotive force may be connected between the first node and the second node and between the first node and the third node.

In addition, in the present invention, it is connected between the first node and the power supply 32 of the power supply device 30 so that even when the supply power 32 is low, the capacitor 110 for constant mode conversion is charged. A diode 172 that allows the voltage to be maintained may be further connected. The diode 172 is connected in the reverse direction so that even if the supply power 32 is lower than the charging voltage of the constant mode conversion capacitor 110 , the energy of the constant mode conversion capacitor 110 is not discharged toward the supply power 32 . . In order to maximize the energy charged in the constant mode conversion capacitor 110, the diode 172 may use a Schottky diode.

And, in an embodiment of the present invention, a zener diode connected between the collector terminal of the rear-end transistor 140 and the supply power 32 to turn off the front-end transistor 130 when the supply power 32 is lowered below the zener voltage. 174 may be further connected. That is, the Zener diode 174 monitors the change in the supply voltage of the power supply and when the regular changeover switch 40 is in standby mode, the supply power 32 becomes higher than the Zener voltage, and the Zener diode 174 conducts and the relay When the driving unit 100 operates in the standby mode, on the other hand, when the normal changeover switch 40 is switched to the normal mode, the supply power 32 is lowered below the standard, and the relay driving unit 100 is operated at all times by the Zener diode 174. It is determined that the mode has been changed, and the normal mode operation is performed accordingly.

Hereinafter, an actual operation process of the standby power cutoff outlet including the condenser for constant mode conversion of the present invention will be described.

First, in order to solve the problem that occurs in the configuration of the conventional standby power cut-off outlet having a regular mode function, in the present invention, the use of the regular changeover switch is the standby power detection function of the outlet and the power supply of the power supply constituting the control circuit. The mechanical operating area was minimized by minimizing the load applied to the constant change switch and heat generated by the load by using it only for the purpose of use.

When using the standby power cutoff function, position the knob of the regular changeover switch so that terminals 1 and 2 are connected to operate the relay driving part of the outlet so that the power supply generates and supplies the supplied power, and the relay driving part is It enables the standby power cutoff function to be performed (refer to FIGS. 2 and 3), and at this time, the capacitor for constant mode conversion is charged.

In the standby power cut-off mode, when the signal of the current sensor unit is below the standard, the relay-off operation should be performed. A high signal enters the base of the second transistor circuit 150, the transistor is turned on, and the current is transferred to the second coil 56 by the supply power. The relay contact 52 is turned off while exiting through the relay, and when the signal of the current sensor unit is greater than the standard, the relay-on operation must be performed. A High signal enters the base of the rear-end transistor 140 is turned on, the collector terminal is in a Low state, the front-end transistor is turned off, the gate voltage of the MOSFET 120 becomes high, and the MOSFET 120 conducts. ) while exiting, the relay contact 55 is turned on.

Next, when you want to switch to the regular mode that does not use the standby power cutoff function, turn the knob of the regular changeover switch so that terminals 2 and 3 are connected to physically cut off the supply power supplied to the relay driving unit 100 of the outlet. position to cut off the power to the power supply so that there is no standby power consumption, and the contact of the relay was forcibly connected to the outlet output terminal so that the power was always connected (see FIG. 4 ).

After the power supply to the relay driving unit 100 is cut off, a process of attaching the relay contacts is required. For this purpose, the present invention charges a capacitor for constant mode conversion in the standby power cut-off mode, and when the power supply to the relay driving unit is released It is configured so that the contact of the relay can be attached by the energy charged in the condenser for constant mode conversion.

That is, when the knob of the regular changeover switch is moved so that the terminals 2 and 3 are connected, the supply power 32 of the power supply device 30 is discharged in a short time, but the supply power 32 and the constant mode conversion capacitor The diode 172 connected between the 110 may act in the reverse direction, so that the charging voltage of the constant mode conversion capacitor 110 may be maintained as it is.

In addition, when the supply power 32 drops below the zener voltage of the zener diode 174, the base of the front-end transistor goes to a low state, the front-end transistor 130 is turned off, and the gate of the MOSFET 120 goes to a high state and the MOSFET ( 120) is turned on, and at this time, the energy charged in the constant mode conversion capacitor 110 exits through the first coil 55 and the MOSFET 120 and attaches the contact 52 to perform the constant mode operation. be able to

Such circuit operation may operate in the same manner even when the power supply of the power supply device is cut off or the reference output voltage is not provided due to a failure of the power supply device, so that the load in use may operate normally.

Therefore, the state transition for the constant power supply is completed, the standby power state becomes 0W, and the constant power supply becomes possible.

Although preferred embodiments of the present invention have been illustrated and described above, the present invention is not limited to the specific embodiments described above, and is common in the technical field to which the present invention pertains without departing from the gist of the present invention as claimed in the claims. Various modifications are possible by those with knowledge. In addition, matters that can be easily inferred from the accompanying drawings should be considered to be included in the content of the present invention even if they are not described in the detailed description, and various modifications should not be individually understood from the technical matters or prospects of the present invention. will be

10: power input terminal 20: outlet output terminal
30: power supply 32: supply power
40: regular changeover switch
50: relay 60: current sensor unit
100: relay driving unit 110: constant mode conversion capacitor
172: diode 174: zener diode

Claims (5)

power input terminal;
an outlet output terminal connected in parallel to the power input terminal;
a power supply connected to the power input terminal to convert AC power into DC power and supply;
a regular changeover switch connected between a first power input terminal of the power input terminal and the power supply device;
a relay connected between the first power input terminal and a first outlet output terminal of the outlet output terminal connected thereto;
a current sensor unit for detecting a load current value between the first power input terminal and the first outlet output terminal; and
Performing a standby power cut-off mode using the power supplied from the power supply and turning on/off the contact point of the relay according to the current value sensed by the current sensor unit when the regular changeover switch is turned on, a relay driving unit configured to perform a regular mode by turning on a contact of the relay when the regular changeover switch is turned off;
including,
The relay driving unit is charging energy while in the standby power cut-off mode and discharging the charged energy when it is changed to the regular mode and includes a constant mode conversion capacitor for driving the relay. Standby power interrupting outlets containing capacitors for
According to claim 1,
The relay is a latch relay comprising a contact that is maintained in an on state even when a current is opened by including a permanent magnet, a first coil that turns on the contact when a current flows, and a second coil that turns off the contact when a current flows ,
The supply power supplied from the power supply device is connected to a first node between the first coil and the second coil in the relay driving unit,
In the relay driving unit, the second node on the opposite side of the first coil and the third node on the opposite side of the second coil selectively regulate the flow of current flowing from the first node to the ground terminal by the power supply including a current interrupting circuit for
The constant mode conversion capacitor is connected to the first node in parallel to charge energy by the supply power. Standby power blocking outlet including a constant mode conversion capacitor.
3. The method of claim 2,
The current cut-off circuit is
Between the second node and the ground terminal, a drain is connected to the first coil side, a source is connected to a ground terminal, and a gate is connected to the first node side. a first transistor circuit comprising a backstage transistor configured to receive a relay-on signal through a base; and
a second transistor circuit coupled between the third node and a ground terminal and configured to receive a relay-off signal to a base;
including,
The front-end transistor is a standby power cutoff outlet including a capacitor for constant mode conversion, characterized in that the gate and the first node of the MOSFET are connected to a collector, and the collector of the rear-end transistor is connected to the base.
4. The method of claim 3,
Standby power blocking outlet including a capacitor for constant mode switching, characterized in that a protective diode for preventing reverse voltage is connected between the first node and the second node and between the first node and the third node.
4. The method of claim 3,
A diode is further connected between the first node and the power supply of the power supply so that the voltage charged in the constant mode conversion capacitor is maintained even when the supply power is lowered,
Standby power blocking outlet including a capacitor for constant mode conversion, characterized in that connected between the collector terminal of the rear-end transistor and the supply power to turn off the front-end transistor when the supply power is lowered below the Zener voltage is further connected.

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