KR20100036464A - Power saving multi socket outlet by minimizing the stanby power and its method - Google Patents

Abstract

PURPOSE: In the power saving multi outlet minimizing the stand-by power and driving method is the controlling supply of power section of the supplementary power supply, the electric power is consumed. The electric power in the section of the controlling supply of power section extrinsic is consumed. In that way the big energy saving effect is obtained. CONSTITUTION: A circuit power control switch(20) controls the electric power supply of the control circuit between an external power source(17) and a circuit power unit. When an elastic conductor(21) interlinks the terminal in which the status of electric power supply status of a supplementary sub power(11) and a main power(10) the same, the circuit power supply close control switch is quarantined. When for the elastic conductor, the status of electric power supply of the supplementary power supply and main power source interlinks the other terminal, the circuit power supply close control switch is connected. Supplies the circuit power supply to the circuit power supply close control switch is the operating time of the control circuit.

Description

Power saving multi socket outlet by minimizing the stanby power and its method

The present invention relates to a power-saving multi-outlet, and more particularly, to a multi-outlet having a power-saving function that consumes power only during actual operation and uses only minimal power during standby. In particular, the present invention senses the current flowing in the main power source 10 when used in a computer system or a home theater system, and has a function of controlling the supply of the sub power source 11 such as a monitor, a printer, a speaker, and a modem, and the sub power source 11. It is a power-saving multi-outlet that minimizes power consumption of the multi-outlet by using power only at the moment of controlling the supply of the power supply.

When the main body of the computer or home theater system connected to the main power source 10 is turned off, the power-saving multi-outlet detects the standby power flowing to the main body to detect that the main body is turned off, and the monitor or speaker connected to the sub power source 11. Cut off the power supply to the lamp. By doing so, even if the user forgets to turn off the device connected to the sub-power source 11 or even turns off the device connected to the sub-power source 11, power consumption can be reduced by fundamentally blocking standby power consumption. .

In recent years, however, electrical appliances themselves are made in production to have significantly lower standby power. Therefore, the power saving effect obtained by blocking the standby power of the electrical appliances connected to the sub-power source 11 by using the existing power-saving multi-outlet is gradually reduced. The power-saving multi-outlet itself consumes power in the process of measuring the current flowing through the main power source 10 or controlling the power supply of the sub power source 11. This power consumption is essential for driving the control circuit 12 included in the power-saving multi-conductor, and it can be said that the power saving effect is smaller than the waste of power by the standby power of the electrical products connected to the sub-power source 11. However, if the standby power of electrical appliances is lowered gradually, the power saving effect of these power saving multi-outlets will be reduced.

The amount of power consumed by the power-saving multi-conductor itself is the sum of the amount of power consumed while detecting the amount of electricity of the main power supply 10 and comparing it with a reference value, and the amount of power consumed while actually controlling the power supply of the sub power source 11. That is, the power consumption of the multi-conductor itself may be divided into “monitoring power”, which is power in a section for monitoring the amount of electricity of the main power source 10, and “operating power”, which is power in a section for controlling power supply of the sub power source 11. Can be. The problem to be solved by the present invention is to provide a power-saving multi-outlet and a method of reducing the power consumption of the multi-outlet itself by minimizing the "monitoring power".

The circuit power control switch 20 is disposed between the circuit power supply unit 16 and the external power supply 17 for supplying power to the control circuit 12, and the control circuit 12 actually cuts off the power supply of the sub power supply 11. Alternatively, power is supplied to the control circuit 12 only when it is supplied. The time when the user turns off or on the main body is judged as a no power supply without power supply, and the means for supplying power to the circuit power supply unit 16 and the time when the control circuit 12 completes operation are determined to determine the circuit power supply unit 16. Means for discontinuing power supply) are included in the present invention.

The circuit power control switch 20 is disposed between the external power source 17 and the circuit power supply unit 16. The circuit power control switch 20 includes four terminals, each terminal representing a power supply state of the main power supply 10 and the sub power supply 11. The circuit power control switch 20 performs a four-stage switching operation by using the magnetic force by the current supplied to the main power supply 10 and the current supplied to the sub power supply 11 and the elastic force of the elastic conductor 21. By the four-stage switching operation, the control circuit 12 controls the power supply of the sub power source 11 in accordance with the point of time when the user turns off or on the main body. Enter By spending most of the time in the "sleeping state," it is possible to achieve power-saving multi-outlets with minimal power consumption.

The power-saving multi-outlet having the minimum standby power of the present invention consumes power only in a section for controlling the power supply of the sub-power source 11, and otherwise, consumes very little power to obtain a large power saving effect.

1 is a block diagram of a conventional power saving multi-outlet. Conventional power-saving multi-outlet is configured by the main power source 10 and a plurality of sub-power source 11, the socket, and by detecting the amount of electricity flowing through the main power source 10 by controlling the power supply of the sub-power source 11. The power saving effect is obtained by blocking the standby power of the source 11 at source. That is, as shown in the figure, when the user turns off the computer main body connected to the main power source 10 when used in the computer system, the electric current flowing through the main power source 10 is sensed using the current transformer CT, and the relay switch SW Cut off the negative power source (11). Therefore, the power supplied to a device such as a monitor or a printer connected to the sub power source 11 is cut off at source. By doing so, even if the user forgets to switch off the device connected to the sub-power source 11 or switches off the device, power consumption due to the consumption of standby power generated can be prevented.

In order to achieve the above object, the conventional power-saving multi-outlet is a reference for determining whether to cut off the electricity quantity measuring unit 13, the secondary power source 11 to measure the amount of electricity flowing in the main power source 10 using the current transformer CT. To operate the control circuit 12 and the control circuit 12, which are composed of a reference value setting unit 14 for setting the amount of electricity to be set and a sub-power driver 15 for actually controlling the power supply of the sub-power 11. The circuit power supply unit 16 for supplying power is included. The control circuit 12 consumes power by itself, which is a power saving effect because the power saved by cutting off the power of the sub power source 11 is larger than the power consumed in this way. However, in recent years, electronic devices such as a monitor, a printer, and a speaker connected to the secondary power source 11 have been produced to have low standby power, and the power saving effect of the conventional power saving multi-outlet is getting smaller. to be.

FIG. 2 is a diagram showing a change in time P of power P consumed by the control circuit 12 of the multi-concentration itself according to a control state when using the aforementioned power-saving multi-outlet. In the figure, section a indicates when the main socket M, which is the main power source 10, is in use, and the sub socket S, which is the sub power source 11, is in use. At this time, the control circuit 12 of the multi-outlet constantly measures the amount of electricity supplied to the main power source 10 and compares it with a reference value to determine that the main socket M is in use and to maintain the power supply of the sub power source 11. . The amount of power consumed by the power consumption P1 consumed while the control circuit 12 measures the amount of electricity of the main power source 10 and compares it with the reference value corresponds to the area of the A region.

When the user turns off the computer or the home theater main body connected to the main socket M at a specific time point t1, the control circuit 12 detects the amount of electricity supplied to the main power source 10 and compares it with the reference value to control the sub-power driver. By operating the relay switch (SW) through (15) to cut off the power supply of the sub-socket (S) of the sub-power (11). The section b indicates such a state. The power supplied to the main socket M, which is the main power supply 10, is interrupted by the user, and the power supply of the sub socket S, which is the sub power supply 11, is supplied to the control circuit 12. It is blocked by. In the process of operating the relay switch SW by the sub-power driver 15, the power consumption increases, so the power consumption by the power consumption P2 in this section corresponds to the area of the B area.

When the power supply of the sub power source 11 is cut off at a specific time point t2, the control circuit 12 detects the amount of electricity supplied to the main power source 10 again and compares it with a reference value to turn off the main body connected to the main power source 10. It is determined that the presence of the power supply and the power supply state of the secondary power source 11 is maintained. This state is indicated by section c. At this time, the power consumed while the control circuit 12 measures the amount of electricity of the main power source 10 and compares the reference value with the reference value is the same as the power consumption (P1) in a section and the amount of power consumed corresponds to the area of the C region. do.

When the user turns on the power of the computer or home theater main body connected to the main socket M at a specific time point t3, the control circuit 12 detects the amount of electricity supplied to the main power source 10 and compares it with the reference value. The relay switch SW is operated through 15 to supply power to the sub-socket S, which is the sub-power 11. The period d indicates such a state, in which power supplied to the main power supply 10 is recovered by the user, and power is supplied to the sub power supply 11 by the control circuit 12. In the process of operating the relay switch SW by the sub-power driver 15, the power consumption increases, so the power consumption by the power consumption P2 in this section corresponds to the area of the D region.

When the power of the sub power source 11 is supplied at a specific time t4, the control circuit 12 detects the amount of electricity supplied to the main power source 10 again and compares it with a reference value to turn on the main body connected to the main power source 10. Determine and keep the power supply state of the sub-power (11). This state is indicated by the e section. At this time, the power consumed while the control circuit 12 measures the amount of electricity of the main power source 10 and compares it with the reference value is the same as the power consumption (P1) in section a or section c and the amount of power consumed is It corresponds to area.

As described above, the amount of power consumed by the multi-conductor itself is A + B + C + D + E, which is the sum of all regions. Among these, the areas corresponding to the amount of power consumed by the power P2 consumed while the multi-outlet controls the power supply of the sub power source 11 are the B and D areas, and the multi-outlet detects the amount of electricity of the main power source 10. The areas corresponding to the amount of power consumed by the power P1 consumed while comparing with the reference value are A, C, and E areas. That is, the power consumption of the multi-conductor itself may be divided into a monitoring power P1 which is a power in a section for monitoring the amount of electricity of the main power supply 10 and an operating power P2 which is a power in a section for operating the relay switch SW. have.

3 is a view showing a change in power of itself according to the control state of the multi-outlet of the present invention. It is an object of the present invention to provide a power saving multi-outlet and a method for reducing power consumption of the multi-outlet itself by minimizing the monitoring power P 1. A process of waking and sleeping the control circuit 12 to operate the control circuit 12 only in sections b and d, which are sections in which the control circuit 12 actually cuts or supplies the power of the sub-power source 11, is included. A method of waking the control circuit 12 by determining the time of waking the control circuit 12 as a no power source without power consumption will be described in detail below. Determining the timing of sleeping the control circuit 12 is not difficult since it is the timing at which the control circuit 12 has completed its operation.

In the section a, the main power source 10 and the sub power source 11 are turned on, and no power is supplied to the circuit power supply unit 16, so that the control circuit 12 does nothing and consumes little power.

Section b consists of three processes. When the user turns off the power of the computer or home theater system main body connected to the main power source 10 at a specific time point t1, a "wake up" process is provided in which power is supplied to the circuit power supply unit 16 by the system described below. Then, at a time t2, the control circuit 12 measures the electric quantity of the main power supply 10 and compares it with a reference value, and operates the relay switch SW through the sub power supply driving unit 15 to supply power to the sub power supply 11. To block. Then, the process enters the "sleep" process of stopping the power supply of the circuit power supply unit 16 at time t3. Consumption in section b consisting of a "wake" process of supplying power to the circuit power supply unit 16, an "operator" process of operating the control circuit 12, and a "return" process of stopping supply of power to the circuit power supply unit 16. The amount of power used corresponds to B1 + B + B2.

In the c section, the main power supply 10 and the sub power supply 11 are turned off, and the power supply is not supplied to the circuit power supply unit 16 as in the a section, so that the control circuit 12 does nothing and the power consumed is Few.

Like the b section, the d section has three processes. When the user turns on the computer or the home theater system main body connected to the main power source 10 at a specific time point t5, a process of "wakeing up" is supplied to the circuit power supply unit 16 by the system described below. Then, at time t6, the control circuit 12 measures the amount of electricity of the main power supply 10 and compares it with a reference value, and operates the relay switch SW through the sub power supply driving unit 15 to turn off the power supply of the sub power supply 11. Supply. Then, the process enters the "sleeping" process of stopping the power supply of the circuit power supply unit 16 at time t7. Consumption in section d includes a "wake" process of supplying power to the circuit power supply unit 16, an "operator" process of operating the control circuit 12, and a "return" process of stopping supply of power to the circuit power supply unit 16. The amount of power applied corresponds to D1 + D + D2.

In the e section, the main power supply 10 and the sub power supply 11 are turned on, and the power supply is not supplied to the circuit power supply unit 16 as in the a section or the c section, so that the control circuit 12 does nothing. There is very little power.

As shown, the control circuit 12 only needs to perform its function when the user turns off or on the power of the main body connected to the main power source 10. In order to do so, a circuit is formed by including a system for supplying power to the circuit power supply unit 16 and interrupting the circuit power supply unit. The circuit power supply unit 16 determines the time when the user turns off or on the main body as no power supply. Means for supplying power and means for stopping the supply of power to the circuit power supply unit 16 by determining when the control circuit 12 has completed operation are included in the present invention.

4 is a view illustrating a time of waking, a time of sleeping, and an operation time of the control circuit of the multi-outlet of the present invention. The core problem to be solved in the present invention is to determine the time of waking or sleeping the control circuit 12 as no power supply without power supply. To this end, it is necessary to first determine the timing of waking and sleeping the control circuit 12.

As shown, the time points at which the control circuit 12 is woken are t1 and t5. A characteristic of the time t1 is that only the main power supply 10 is switched off while the main power supply 10 and the sub power supply 11 are both on. A characteristic of the time t5 is that only the main power source 10 is switched on while the main power source 10 and the sub power source 11 are both off. The common point between the time points t1 and t5 is that the sub power source 11 is not changed, and only the main power source 10 has a change in power supply. This change is caused by the user and appears when the user turns off the main body connected to the main power source (t1) or turns on the main body (t5). As a result, the time to wake up the control circuit 12 is when the power supply of the main power supply 10 changes from "on to off" or "off to on".

As shown, the time points for sleeping the control circuit 12 are t3 and t7. A characteristic of the time t3 is that the sub power source 11 in the on state is turned off along with the off state of the main power source 10. A characteristic of the time t7 is that the sub power source 11 in the off state is turned on along with the on state of the main power source 10. The common point between the time points t3 and t7 is that the main power source 10 has no change, and only the sub power source 11 has a change in power supply. This change is not caused by the user but by the control circuit 12 performing its task. As a result, the time to reload the control circuit 12 is when the power supply of the sub power source 11 changes from "on to off" or "off to on".

5 (a) is a table showing the power supply state of the control circuit according to the power supply state of the main power supply and the sub-power supply in the present invention, (b) is a view showing the flow of the signal and control. In the present invention, the circuit power control switch 20 is connected to the circuit power supply unit 16 to wake up, operate, and re-enable the control circuit 12. In order to explain the logic for operating this circuit power control switch 20, as shown in the table of Fig. 5A, the main power supply 10, the sub power supply 11, and the control circuit 12 in each state. The power supply state of is shown. The section indicated by T0, T1, etc. in the table corresponds to the section shown in FIG. In the table of FIG. 5A, a state in which the power of the main power source 10, the sub power source 11, and the control circuit 12 are supplied is represented by “○”, and a state in which the power is cut off is represented by “×”. It was.

As shown in the table of FIG. 5A, the sleeper of the control circuit 12 is characterized in that the power supply states of the main power supply 10 and the sub power supply 11 are the same. The characteristic of the actuator of the control circuit 12 is that the power supply states of the main power supply 10 and the sub power supply 11 are different. As a result, when the power supply state of the main power supply 10 and the sub power supply 11 is the same, the control circuit 12 is a sleeper, and when the power supply state of the main power supply 10 and the sub power supply 11 is changed, the control circuit 12 is awakened. Start it up and resume it.

The flow of signals for power supply control of the control circuit 12 starts from the user as shown in FIG. The user generates a large change in the current flowing in the main power source 10 by manually turning off or supplying power of the main body connected to the main power source 10. The large current change generated in the main power supply 10 is received as a signal to wake up the control circuit 12 in the water surface. The awakened control circuit 12 performs a natural control task of supplying or cutting off the power of the sub power source 11. At this time, the sub power source 11 generates a large current change, and receives the large current change as a signal to sleep the control circuit 12. Therefore, the control circuit 12 enters the sleeper again.

As a result, the time to wake up or wake up the control circuit 12 is due to a large current change, which is used as the power for driving the circuit power control switch 20. That is, the control circuit 12 is switched to a sleeper or an actuator according to the situation by receiving a large current change of the main power supply 10 and the sub power supply 11 as a signal and using it as a power for operating the circuit power control switch 20. You can do it.

6 is a view illustrating a switching concept of the circuit power control switch 20 in the present invention. As shown, the circuit power control switch 20 has four terminals M-on, M-off, S-on and S-off. Each terminal represents a power supply state of the main power supply 10 and the sub power supply 11. The iron ball may be connected to each terminal, and the circuit power control switch 20 may be turned on or off depending on the position of the iron ball. The iron ball is expressed to show the concept of the circuit power control switch 20 and does not represent the actual configuration of the invention.

6A illustrates a state in which power is supplied to the main power supply 10 and the sub power supply 11. In this state, since the iron ball connects the M-on terminal and the S-on terminal, the circuit power control switch 20 is in an off state where no current flows. (b), since the power is supplied to the sub-power 11 while the power of the main power supply 10 is cut off, since the iron ball connects the M-off terminal and the S-on terminal, the circuit power control switch 20 has a current. Flows. Therefore, the control circuit 12 operates to cut off the power supply of the sub power supply 11. In (c), since the bead connects the M-off terminal and the S-off terminal while the power supply of the sub power source 11 and the main power source 10 is cut off, no current flows in the circuit power control switch 20. (d) has no power supply of the sub-power 11 in the state of supplying the power of the main power supply 10, so the iron ball connects the M-on terminal and the S-off terminal, so that the current in the circuit power control switch 20 Flow. Therefore, the control circuit 12 operates to supply power to the sub power source 11.

As shown in FIG. 6, it is preferable to use electromagnetic force in the case of the M-on and S-on terminals among the four pulling terminals pulling iron balls. When power is supplied to the main power supply 10 and the sub power supply 11, current flows, and by using the magnetic force generated by the current flowing at this time, the iron ball can be attracted to the M-on or S-on terminal. The force that pulls the iron ball out of the remaining M-off and S-off terminals preferably uses gravity, elasticity, or magnetic force of the permanent magnet, which is independent of electric force.

7 is a view showing a circuit power control switch driving method using an elastic force and an electromagnetic force. As shown in the drawing, a terminal in a state where power is supplied to the main power source 10 and the sub power source 11 represents an electromagnet including the coil 22 to use an electromagnetic force, and the main power source 10 and the sub power source 11 ), The terminal that indicates the power off state represents a general terminal. The elastic conductor 21 is connected to the M-off terminal and the S-off terminal by the elastic force if there is no force from the outside. Then, the elastic conductor 21 may be connected to the M-on terminal and the S-on terminal by the electromagnetic force of the M-on terminal and the S-on terminal.

7A illustrates a circuit power control switch by connecting the M-off terminal and the S-off terminal to the elastic conductor 21 as shown in the state in which power is cut off from the main power supply 10 and the sub power supply 11. No current flows through the numeral 20. (b) indicates that electromagnetic force is generated at the M-on terminal by the current flowing in the main power supply 10 while the power is supplied to the main power supply 10, and the elastic conductor 21 connects the M-on terminal and the S-off terminal. As a result, a current flows through the circuit power control switch 20. When power is supplied to both the main power supply 10 and the sub power supply 11, the elastic conductor 21 is connected to the M-on terminal and the S-on terminal by electromagnetic force, so that no current flows in the circuit power control switch 20. . Then, when the power supply of the main power source 10 is cut off, the elastic conductor 21 connects the M-off terminal and the S-on terminal so that a current flows in the circuit power control switch 20.

8 is a view showing a driving method of the circuit power control switch 20 in the present invention. As shown, among the four terminals of the circuit power control switch 20, the M-on terminal indicating the power supply state of the main power supply 10 is provided with a coil 22 to operate as an electromagnet, and both ends of the coil 22 Each is connected to an external power source 17 and the main power source 10. That is, the current supplied to the main power source 10 is supplied after passing through the coil 22 portion of the M-on terminal. The S-on terminal indicating the power supply state of the sub power source 11 is also provided with a coil 22 to operate as an electromagnet, and both ends of the coil 22 are connected to the external power source 17 and the sub power source 11, respectively. That is, the current supplied to the sub power source 11 is supplied after passing through the coil 22 portion of the S-on terminal.

9 is a view showing the configuration of the present invention. As shown, the present invention is a big difference that the circuit power control switch 20 is additionally included as compared to the conventional power-saving multi-outlet. The circuit power control switch 20 included in the present invention is disposed between the external power source 17 and the circuit power supply unit 16 to control the power supply of the control circuit 12. The circuit power control switch 20 does not need a separate power supply by performing a switching operation using a magnetic force by the current supplied to the main power supply 10 and the current supplied to the sub power supply 11.

10 is a diagram showing an actual circuit diagram of the present invention. As shown, the electric current measuring unit 13 for measuring the current supplied to the main power source 10 using the current transformer CT, and flows to the main power source 10 to determine whether or not the power supply of the sub-power source 11 is supplied. Reference value setting unit 14 for setting the reference value of the current for comparing the current, the sub-power driver 15 for controlling the power of the sub-power 11 using the relay switch (SW), the electric quantity measuring unit 13 And a circuit power supply unit 16 for supplying power to the reference value setting unit 14 and the sub-power driver 15, a circuit power control switch 20 connected between the external power source 17 and the circuit power supply unit 16, and a main power source ( 10) It consists of a socket and a sub power supply 11 socket.

Since the electric quantity measuring unit 13, the reference value setting unit 14, and the sub-power driver 15 and the like are well known technologies, detailed descriptions thereof will be omitted. In addition, a surge interruption part, an overvoltage interruption part, and the like are shown in the circuit where the external power source 17 enters, but the detailed description is omitted since it is a known technique regardless of the spirit of the present invention.

1 is a block diagram of a conventional power-saving multi-outlet.

2 is a change in power consumed in the control circuit of the multi-outlet itself according to the control state in the conventional power-saving multi-outlet.

3 is a change in power consumed in the control circuit of the multi-outlet itself according to the control state of the multi-outlet of the present invention.

Figure 4 is a view showing the time and wake up time and the operation time of the control circuit of the multi-outlet of the present invention.

Figure 5 (a) is a table showing the power supply state of the control circuit according to the power supply state of the main power supply and the sub-power supply in the present invention, (b) is a view showing the flow of signals and control.

6 is a view showing a switching concept of a circuit power control switch in the present invention.

7 is a view showing a circuit power control switch driving method using an elastic force and an electromagnetic force.

8 is a view showing a driving method of a circuit power control switch in the present invention.

9 is a block diagram of the present invention.

10 is an actual circuit diagram of the present invention.

<Description of the reference numeral>

10 ... Mains 11 ... Subs

12 ... control circuit 13 ... electric quantity measuring part

14 ... Reference value setting section 15 ... Sub power drive section

16 Circuit power supply 17 External power supply

20.Circuit power control switch 21.Elastic conductor

22 ... coil

Claims (4)

Electric quantity measuring unit 13 for measuring the current supplied to the main power source 10, the reference value setting unit 14 for setting the reference value of the current in order to determine whether the power supply of the sub-power 11, sub-power 11 A control circuit 12 consisting of a sub-power driver 15 for controlling a power supply of the circuit and a circuit power supply unit 16; and an external power source 17, a main power source 10, and a sub-power source 11 that receive power from the outside. In a typical power-saving multi-outlet consisting of, A circuit power control switch 20 disposed between the external power source 17 and the circuit power supply unit 16 to control the power supply of the control circuit 12; The circuit power control switch 20 has a terminal (M-on, M-off) that is operated by the electromagnetic force of the coil 22 according to whether or not the power supply of the main power supply (10) and whether the power supply of the sub-power (11) Accordingly, terminals S-on and S-off operated by the electromagnetic force of the coil 22 and elastic conductors 21 connecting the respective terminals are included; When the elastic conductor 21 connects the terminals of the same power supply state of the main power supply 10 and the sub power supply 11, the circuit power control switch 20 is cut off. Each terminal is arranged so that the switch 20 is connected; When the circuit power control switch 20 performs the switching operation by the electromagnetic force by the current supplied to the main power source 10 and the sub-power source 11 and the elastic force of the elastic conductor 21 to operate the control circuit 12 Power-saving multi-outlet with minimal standby power, characterized in that the circuit power supply only. The method of claim 1, Coils mounted at terminals M-on and M-off operated according to whether the main power 10 of the circuit power control switch 20 is supplied with power are connected to the external power 17 and the main power 10. The coils mounted on the terminals S-on and S-off operating according to the power supply of the sub power source 11 may include both ends connected to the external power source 17 and the sub power source 11. Power-saving multi-outlet with minimal standby power. The method of claim 1, The elastic conductor of the circuit power control switch 20 includes a terminal M-on indicating a state in which power is supplied to the main power source 10 and a terminal S-on indicating a state in which power is supplied to the sub power source 11. ) Power-saving multi-concentration with minimal standby power, characterized by replacing the conductive sphere to connect the four terminals by the electromagnetic force and gravity of the coil mounted on the). A first step in which a large change in current flowing in the main power source 10 occurs by manually turning off or supplying power of the main body connected to the main power source 10 by the user; A second step of receiving a large current change generated in the main power supply 10 as a signal and supplying power to the control circuit 12 through the circuit power supply control switch 20; A third step in which the control circuit 12 performs an original control task of supplying or interrupting power of the sub power source 11; And A fourth step of receiving the current change generated in the sub power supply 11 as a signal and cutting off the power of the control circuit 12 through the circuit power control switch 20; Method of driving a power-saving multi-concentrator minimized standby power, characterized in that it comprises a.

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