KR101273708B1 - Intelligent outlet for power saving and driving method thereof - Google Patents

Abstract

PURPOSE: Energy-saving intelligent multiple outlet strips and an operation method thereof are provided to maximize user convenience by automatically determining the level of an electronic device's power supply without user intervention. CONSTITUTION: If load power is received from at least one first detector (20) when an initial period of time is smaller than a predetermined time for reference standby power, a control unit (40) outputs a relay cut-off signal for turning off a relay (50) and periodically outputs at least one load detection signal. When the input power is supplied to an electronic device by turning off at least one relay, at least one second detector (70) measures load resistance of the electronic device in response to at least one load detection signal and outputs a reset signal for turning on the relay. [Reference numerals] (20) First detector; (30) Memory; (40) Control unit; (60) Auxiliary power; (70) Second detector; (IN) Input power; (LD) Electronic device

Description

Power-saving intelligent multi-outlets and how they work {INTELLIGENT OUTLET FOR POWER SAVING AND DRIVING METHOD THEREOF}

The present invention relates to a power saving intelligent multi-outlet and a method of operating the same, and more particularly, to a power saving intelligent multi-outlet that automatically detects a load state and automatically connects.

The proliferation of electronic devices has led to a surge in the use of multi-outlets. A multi-outlet (or multi-tap) is a mobile outlet that allows you to plug in multiple plugs and connects them to a wall outlet that allows you to use several electrical appliances at the same time.

On the other hand, many of the recently spread electronic devices are often operated by a remote control for the user's convenience. Since the electronic devices operated by the remote controller must be able to receive signals transmitted from the remote controller at all times, power is consumed even when the user does not use the electronic device. In addition, among the electronic devices that are not operated by the remote control, as the user interface of recently released electronic devices is changed to the electronic touch detection method instead of the conventional mechanical switch, power consumption is always detected to detect the user's input. Even though the user does not use the electronic device, the power consumed by the electronic device to sense the user's input at all times is called standby power, and is one of the main causes of the power shortage.

Various methods have been proposed to cut off such standby power, and one of them is to provide a separate switch to each of a plurality of outlets of a multi-outlet to individually supply or cut off power for each electronic device connected to each outlet. However, the biggest reason that the electronic device consumes standby power is to provide convenience for the user. In other words, even if an individual switch is provided to the multi-outlet, the user has to manually operate the individual switch manually. Therefore, the user does not use the switch even when using a multi-outlet without a switch or a multi-outlet equipped with a switch. Many did not have a significant effect on the reduction of standby power.

And it is well known that multi-outlets with multiple electronic devices are vulnerable to electrical fires. This is because a large number of electronic devices can be connected to the multi-outlet. In recent years, as the number of electronic devices exceeding the number of electronic devices that can be connected to the multi-outlet increases, it is frequently used to connect the multi-outlets to other multi-outlets. This provided a variety of sources of electrical fires, such as overcurrent, which increased the likelihood of causing electrical fires.

Accordingly, Korean Patent No. 10-1137234 (filed Dec. 12, 2008, Applicant: Entec Korea Co., Ltd., name: Power-saving outlet and its operation method) measures the load power of the connected electronic device, In this case, the power supply to the electronic devices is automatically cut off to reduce standby power consumption. That is, even if the user does not directly cut off the power supplied to the electronic device, the electronic device determines that it is in the standby state and automatically cuts off the power supply to conveniently reduce the standby power consumption.

However, while the above patent automatically cuts off the power supply to the electronic device, in order to supply power to the electronic device from which the power supply is cut off, it requires user intervention. In other words, only half of the automation was implemented in the form of automatic shut-off and manual supply, not automatic shut-off and automatic supply of power to the appliances. This still requires the user's intervention, causing inconvenience to the user, there is a case that the user selects the convenience rather than the reduction of standby power consumption, there is a limit that does not effectively reduce the standby power consumption.

An object of the present invention is to provide a power-saving intelligent multi-outlet that can sense the state of the connected electronic devices automatically cut off the standby power, as well as automatically supply power.

According to an aspect of the present invention, an intelligent power-saving multi-concentration includes at least one relay for applying or blocking input power to an electronic device that is electrically connected; At least one first detector configured to detect load power consumed by the electronic device by sensing the input power applied to the electronic device when the relay is turned on and the input power is applied to the electronic device; A memory for storing reference standby power; Receives the load power from the at least one first detector, stores the load power received for a predetermined initial time after the input power is applied to the electronic device as the reference standby power, in the memory, and an initial time. Thereafter, when the load power is less than the reference standby power for a predetermined time period by comparing the received load power with the reference standby power, a relay blocking signal for turning off the relay is output, and at least one load detection signal periodically. A control unit for outputting; And when the input power applied to the electronic device is cut off when the at least one relay is turned off, the load resistance of the electronic device is measured in response to the at least one load detection signal, and the relay in response to the measured load resistance. It includes; at least one second detector for outputting a reset signal for turning on.

Each of the at least one second detector is configured to interrupt electrical connection between each of the at least one second detector and the electronic device when the reset signal is output to the relay.

The power saving intelligent multi-outlet may further include an auxiliary power supply supplied to the at least one second detector so that the at least one second detector can measure the load resistance of the electronic device.

The power saving intelligent multi-outlet further includes a transformer for generating the auxiliary power by reducing the input power.

The controller may output the relay cutoff signal to the relay when the load power received by each of the at least one first detector exceeds a predetermined individual maximum reference power.

The controller may set the individual maximum reference power by using the load power received by each of the at least one first detector after the initial time, and store the individual maximum reference power in the memory.

The control unit outputs the relay cutoff signal to the relay when the sum of the load powers received by each of the at least one first detector exceeds a predetermined integrated maximum reference power.

After the initial time, the controller sets the integrated maximum reference power by using the sum of the load powers received by each of the at least one first detector, and stores the integrated maximum reference power in the memory.

Operation method of the power saving intelligent multi-outlet according to an embodiment of the present invention for achieving the above object is a method of operating a power saving intelligent multi-outlet having at least one relay, at least one first and second detectors, memory and control unit The method of claim 1, further comprising: measuring load power from an input power source applied to the electronic device when the at least one first detector is electrically connected to the electronic device; Receiving, by the controller, the load power received for a predetermined initial time after the input power is applied to the electronic device and storing the load power in the memory as a reference standby power; Determining, by the controller, whether the load power received after the initial time is equal to or less than the reference standby power; Turning off the relay so that the input power is not applied to the electronic device by outputting a relay cutoff signal when the load power is less than or equal to the reference standby power for a predetermined time or more; The at least one second detector measuring the load resistance of the electronic device; Determining, by the at least one second detector, whether the load resistance is greater than or equal to a predetermined reference load resistance; And turning on the relay by outputting a reset signal when the load resistance is greater than or equal to the reference load resistance by the at least one second detector.

The operation method of the power saving intelligent multi-outlet may further include disconnecting an electrical connection with the electronic device after the at least one second detector outputs the reset signal.

The step of determining whether the reference load resistance or more and the step of turning on the relay is performed by the controller.

Accordingly, the power saving intelligent multi-outlet and the method of operating the same according to the present invention detect whether the electronic device connected to the multi-outlet is in the standby state, automatically shut off the power supply, and detect whether the electronic device requires power supply It is possible to automatically re-supply power when the electronic device requires power supply. Therefore, the power supply is automatically determined according to the state of the electronic device without user intervention, thereby maximizing user convenience. Standby power consumption can be significantly reduced. In addition, standby power consumption can be significantly reduced, helping to reduce power shortages. In addition, by cutting off the power applied to the electronic device by measuring the load power, it is possible to prevent the occurrence of electrical fire due to overcurrent, short circuit.

1 illustrates a power saving intelligent multi-outlet according to an embodiment of the present invention.
2 illustrates a method of operating power saving intelligent multi-concentration according to an embodiment of the present invention.

In order to fully understand the present invention, operational advantages of the present invention, and objects achieved by the practice of the present invention, reference should be made to the accompanying drawings and the accompanying drawings which illustrate preferred embodiments of the present invention.

Hereinafter, the present invention will be described in detail with reference to the preferred embodiments of the present invention with reference to the accompanying drawings. However, the present invention can be implemented in various different forms, and is not limited to the embodiments described. In order to clearly describe the present invention, parts that are not related to the description are omitted, and the same reference numerals in the drawings denote the same members.

Throughout the specification, when an element is referred to as " including " an element, it does not exclude other elements unless specifically stated to the contrary. The terms "part", "unit", "module", "block", and the like described in the specification mean units for processing at least one function or operation, And a combination of software.

1 illustrates a power saving intelligent multi-outlet according to an embodiment of the present invention.

In FIG. 1, the power saving intelligent multi-outlet 1 may be connected to four electronic devices as an example, but the power saving intelligent multi-outlet 1 of the present invention may connect at least one electronic device, and may include five or more electronic devices. It is obvious that it can be extended to connect.

Referring to FIG. 1, the power saving intelligent multi-outlet 1 of the present invention includes a switch unit 10, a first detector 20, a memory 30, a controller 40, a relay unit 50, and an auxiliary power supply 60. ) And a second detection unit 70.

The input power source IN is a power source input to the multi-outlet 1, for example, when the multi-outlet 1 uses a domestic commercial power source, an AC power source of 220V is input.

The switch unit 10 is a separate mechanical switch provided by the existing multi-outlet, so that the user can block power from being applied to the electronic device LD in order to prevent standby power consumption manually. This has the advantage that the user can clearly recognize the power-off state by using a mechanical switch, but the multi-outlet 1 according to the present invention can automatically cut off and restore the standby power consumption, even if omitted It's okay. In addition, as shown in FIG. 1, a single switch may be implemented in the form of an integrated switch to completely block supply of power to the multi-outlet 1.

The first detector 20 includes a plurality of first detectors. The plurality of first detectors are provided corresponding to the number of electronic devices LDs that can be connected to the multi-outlets, and detect the load power of the corresponding electronic devices LD, respectively.

When the at least one electronic device LD electrically connected to the memory 30 is electrically connected to the corresponding relay RL, the corresponding first detector of the first detector 20 is connected to the relay RL. The initial detected load power of the electronic device is stored as the reference standby power. In this case, the memory 30 separately stores load powers detected by each of the plurality of first detectors. That is, the memory 30 stores a number of reference standby powers corresponding to the number of currently connected electronic devices. Each of the plurality of first detectors may directly transmit the load power detected to the memory 30 and store the load power as reference standby power. However, the load power is transmitted to the controller 40 so that the controller 40 waits for the initial detected load power. It is desirable to store in the memory 30 as electric power. Herein, the initially detected load power refers to load power measured for a predetermined initial time (for example, 0.2 seconds) after the input power IN is supplied to a predetermined electronic device. It may be a load power that is.

In addition, the memory 30 may store and store the individual maximum reference power and the integrated maximum reference power available in the multi-outlet 1.

The controller 40 receives load power of each of the electronic devices detected by each of the plurality of first detectors of the first detector 20, load power of the received electronic devices and a plurality of reference standby powers stored in the memory 30. If the load power detected by the first detector is less than or equal to the corresponding reference standby power for a predetermined time (for example, 1 to 10 seconds) by comparing the corresponding reference standby power, the relay cutoff signal of the relay unit 50 is compared. Output to a corresponding relay among the plurality of relays (RL). That is, when it is determined that the load power detected by the first detector is equal to or less than the reference standby power stored in the memory 30, the controller 40 determines that the connected electronic device is in the standby state. Therefore, since the current consumed by the electronic device can be determined to be standby power, the power supplied to the electronic device can be cut off by transmitting a relay cutoff signal to the corresponding relay.

In addition, if the individual maximum reference power and the integrated maximum reference power are stored in the memory 30, the controller 40 determines whether each of the load powers detected by each of the plurality of first detectors exceeds the individual maximum reference power, Even when the power exceeds the individual maximum reference power, it is possible to cut off the power supplied to the electronic device by transmitting a relay disconnect signal to the corresponding relay. If the total of the load powers detected by each of the plurality of first detectors exceeds the integrated maximum reference power, and if the total of the load powers exceeds the integrated maximum reference power, the relay blocking signal is transmitted to at least one relay of the plurality of relays. By transmitting the power can be cut off the power supplied to the electronic device. That is, it is possible to prevent the occurrence of electrical fires due to the occurrence of overcurrent, short circuit, spark, leakage.

The controller 50 transmits the load detection signal periodically (for example, 1 second) to the second detector corresponding to the relay, in which the relay blocking signal is transmitted.

The relay unit 50 includes a plurality of relays RL, and each of the plurality of relays RL corresponds to an input power transmitted through a corresponding first detector in response to a relay cutoff signal applied from the controller 40. Blocks the application to the electronic device (LD).

In addition, the plurality of relays RL are connected such that input power may be applied to the corresponding electronic device LD again in response to a reset signal output from the corresponding second detector among the plurality of second detectors.

That is, each of the plurality of relays RL cuts off the input power applied to the electronic device in response to the relay cutoff signal, and applies the cut-off input power back to the electronic device in response to the reset signal.

The second detector 70 includes a plurality of second detectors, each of the plurality of second detectors measuring load resistance of a corresponding electronic device in response to a load detection signal transmitted from the controller 40, and specifying a specified load. When the resistance is greater than or equal to the predetermined reference load resistance, the reset signal is output to the corresponding relay RL so that the relay can apply the input power back to the electronic device.

The reference load resistance may be stored in each of the plurality of second detectors, or may be stored in the memory 30. In the above description, the second detector stores the reference load resistance having a fixed resistance value. However, the reference load resistance may also be calculated and stored in the memory by using the load power detected by the first detector. In the present invention, the control unit 40 determines whether the electronic device is in a standby state or an operating state, and since the first detector measures the load power of the electronic device, the control unit 40 determines the load resistance when the electronic device is in the operating state. Can be calculated. Therefore, when the control unit 40 calculates the load resistance of the operating state of the electronic device and stores the load resistance in the memory 30 as the reference load resistance, the control unit 40 may set a reference load resistance that varies according to the type or state of the connected electronic device.

Each of the plurality of second detectors may further include a switch that outputs a reset signal and simultaneously cuts off the electrical connection to the electronic device, and thereafter, when the corresponding relay is again cut off (off), the switch is electrically connected to the electronic device. have. That is, each of the plurality of second detectors is electrically connected to the electronic device when the corresponding relay is turned on, and is electrically connected to the electronic device when the corresponding relay is turned off. This is because the second detector performs an operation only while the input power is not applied to the electronic device.

The auxiliary power source 60 is a power source used by the plurality of second detectors of the second detection unit 70 to sense the load of the electronic device. In the multi-outlet 1 of the present invention, the second detector measures the load resistance of the electronic device in a state where the relay is cut off, that is, the input power IN is not supplied to the electronic device. Therefore, in order to measure the load resistance of the electronic device requires a separate power supply to the electronic device. Since it is simply a power source for measuring the magnitude of the load resistance, applying a high voltage power source is a waste of power because it generates unnecessary power consumption. Accordingly, in the present invention, the multi-outlet 1 includes an auxiliary power supply 60 having a voltage level (for example, 5 V) lower than the input power supply IN, so that the second detector can measure the magnitude of the load resistance of the electronic device. Make sure The auxiliary power supply 60 may be implemented as a battery, or in some cases, may be implemented as a transformer for dropping the voltage level by receiving the input power IN.

2 illustrates a method of operating power saving intelligent multi-concentration according to an embodiment of the present invention.

Referring to FIG. 1, the operation method of the power saving intelligent multi-outlet of FIG. 2 is described. In the operation method of the power saving intelligent multi-outlet according to the present invention, input power is first applied to the multi-outlet 1, and the electronic device is a multi-outlet ( Is electrically connected to 1).

When the input power is applied and the electronic device is connected to the multi-outlet 1, the load of the electronic device LD electrically connected to at least one first detector of the first detector 20 through the corresponding relay RL. The power is first detected (S11).

The controller 40 sets the load power detected during the initial predetermined time period among the load powers detected by the at least one first detector as the reference standby power and stores the load power in the memory 30 (S12).

The at least one first detector secondly detects the load power of the corresponding electronic device.

The controller 40 receives the load power detected by the at least one first detector in a second manner, and determines whether the received detection load power is equal to or less than the reference standby power stored in the memory 30 (S14).

If it is determined that the load power detected second is not lower than the reference standby power, the controller 40 determines that the electronic device is not in the standby state while the electronic device is operating, and the input power IN continues to be applied to the electronic device. It does not control the relay (RL) so that it can be (S15). The at least one first detector again detects the load power of the electronic device at second (S13).

On the other hand, if it is determined that the load power detected second is less than or equal to the reference standby power, the controller 40 determines that the electronic device is in the standby state, and the relay RL so that the input power IN is not continuously applied to the electronic device. The relay is turned off by outputting a relay blocking signal for blocking the signal (S16).

When the relay is turned off and the input power IN is not applied to the electronic device, the controller 40 outputs a load detection signal to at least one second detector of the plurality of second detectors of the second detector 70, and at least One second detector receives an input power source IN and a separate auxiliary power source 60 in response to a load detection signal separately applied to measure a load resistance of a corresponding electronic device (S17).

Each of the at least one second detector determines whether the detected load resistance of the electronic device is greater than or equal to the preset reference load resistance (S18).

If the load resistance of the electronic device detected by the second detector is greater than or equal to the reference load resistance, it may be determined that the electronic device intends to perform the operation again. Therefore, the second detector outputs a reset signal to the corresponding relay RL. Turn on the relay (S19). At this time, the second detector blocks the electrical connection with the electronic device. When the relay is turned on, the input power IN is supplied to the electronic device again, and the corresponding first detector detects the load power of the electronic device as primary again (S11).

However, if the detected load resistance is not higher than the reference load resistance, the second detector does not output the relay RL reset signal, and the relay RL remains off to supply the input power IN to the electronic device. Do not.

As described above, the power saving intelligent multi-outlet according to the present invention determines whether the connected electronic device is in a standby state, and automatically cuts off the power supply, and detects whether the electronic device requires power supply to perform an operation. It can automatically power up again if it needs to be supplied. Therefore, the power supply is automatically determined according to the state of the electronic device without user intervention, thereby maximizing user convenience. Standby power consumption can be significantly reduced. In addition, standby power consumption can be significantly reduced, helping to reduce power shortages. In addition, by cutting off the power applied to the electronic device by measuring the load power, it is possible to prevent the occurrence of electrical fire due to overcurrent, short circuit.

The method according to the invention can be embodied as computer readable code on a computer readable recording medium. A computer-readable recording medium includes all kinds of recording apparatuses in which data that can be read by a computer system is stored. Examples of the recording medium include a ROM, a RAM, a CD-ROM, a magnetic tape, a floppy disk, an optical data storage device, and the like, and a carrier wave (for example, transmission via the Internet). The computer readable recording medium can also be distributed over network coupled computer systems so that the computer readable code is stored and executed in a distributed fashion.

While the present invention has been particularly shown and described with reference to exemplary embodiments thereof, it is evident that many alternatives, modifications and variations will be apparent to those skilled in the art.

Therefore, the true technical protection scope of the present invention will be defined by the technical spirit of the appended claims.

Claims (11)

At least one relay for applying or disconnecting input power to an electronic device that is electrically connected;
At least one first detector configured to detect load power consumed by the electronic device by sensing the input power applied to the electronic device when the relay is turned on and the input power is applied to the electronic device;
A memory for storing reference standby power;
Receives the load power from the at least one first detector, stores the load power received for a predetermined initial time after the input power is applied to the electronic device as the reference standby power, in the memory, and an initial time. Thereafter, when the load power is less than the reference standby power for a predetermined time period by comparing the received load power with the reference standby power, a relay blocking signal for turning off the relay is output, and at least one load detection signal periodically. A control unit for outputting; And
When the at least one relay is turned off and input power applied to the electronic device is cut off, the load resistance of the electronic device is measured in response to the at least one load detection signal, and the relay is responded to in response to the measured load resistance. At least one second detector for outputting a reset signal for turning on the power saving intelligent multi-outlet.
The method of claim 1, wherein each of the at least one second detector is
And outputting the reset signal to the relay cuts off an electrical connection between each of the at least one second detector and the electronic device.
The method of claim 1, wherein the power saving intelligent multi-outlet
And an auxiliary power supply supplied to the at least one second detector so that the at least one second detector can measure the load resistance of the electronic device.
The power saving intelligent multi-outlet of claim 3, wherein
And a transformer for generating the auxiliary power by reducing the input power.
The apparatus of claim 1, wherein the control unit
And when the load power received by each of the at least one first detector exceeds a predetermined individual maximum reference power, outputting the relay cutoff signal to the relay.
The method of claim 5, wherein the control unit
After the initial time, the power saving intelligent multi-outlet, characterized in that for setting the individual maximum reference power by using the load power received by each of the at least one first detector to store in the memory.
The apparatus of claim 1, wherein the control unit
And outputting the relay disconnect signal to the relay when the sum of the load powers received at each of the at least one first detector exceeds a predetermined integrated maximum reference power.
The method of claim 7, wherein the control unit
And after the initial time, the integrated maximum reference power is set and stored in the memory by using the sum of the load powers received by each of the at least one first detectors.
A method of operating a power saving intelligent multi-outlet having at least one relay, at least one first detector and a second detector, a memory, and a control unit,
Measuring load power from an input power source applied to the electronic device when the at least one first detector is electrically connected to the electronic device;
Receiving, by the controller, the load power received for a predetermined initial time after the input power is applied to the electronic device and storing the load power in the memory as a reference standby power;
Determining, by the controller, whether the load power received after the initial time is equal to or less than the reference standby power;
Turning off the relay so that the input power is not applied to the electronic device by outputting a relay cutoff signal when the load power is less than or equal to the reference standby power for a predetermined time or more;
The at least one second detector measuring the load resistance of the electronic device;
Determining, by the at least one second detector, whether the load resistance is greater than or equal to a predetermined reference load resistance; And
And outputting a reset signal to turn on the relay if the at least one second detector has the load resistance equal to or greater than the reference load resistance.
The method of claim 9, wherein the power saving intelligent multi-outlet is operated.
And blocking the electrical connection with the electronic device after the at least one second detector outputs the reset signal.
10. The method of claim 9, wherein determining whether the reference load resistance is equal to or greater than turning on the relay
Operating method of the power saving intelligent multi-outlet, characterized in that performed by the control unit.

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