KR101037760B1 - System and complex switch for blocking standby power - Google Patents

Abstract

PURPOSE: A hybrid switch for blocking standby power and standby electric power blocking system are provided to integrally manages a blocking of a standby power. CONSTITUTION: A control unit(1170) blocks supplement of a second AC power through controlling power switching unit(1050) if a calculated power consumption is under a set standby power or over a set reference over current power. The control unit transmits blocking of a second AC power to a user through controlling an output unit(1110). The control unit distinguishes standby stage and a performance state of a socket through an identified change pattern of a consumption power amount of the socket.

Description

Standby Power Shutdown System and Composite Switch for Standby Power Shutdown {SYSTEM AND COMPLEX SWITCH FOR BLOCKING STANDBY POWER}

The present invention relates to a standby power cut-off system and a composite switch for standby power cut-off, specifically, cut off standby power of a connected outlet, reduce power consumed by a processor mounted in the standby switch to cut power, and output to an outlet. The present invention relates to a standby power cutoff system and a composite switch for standby power cutoff, which can efficiently calculate the amount of power that is a reference for determining whether to cut off power.

In general, home and office use a variety of electronic products such as computers, laptops, TVs, DVD players, refrigerators, washing machines.

The user using such an electronic product is connected to an outlet to supply power to the electronic product. Users keep their appliances plugged into outlets even when they are not habitual. The electronic products that are being powered continue to consume power by using some power to prepare for receiving commands from the user even though they are not operating. This power consumption is generally referred to as standby power.

Standby power is wasteful in that it consumes unnecessary power and can save energy by drastically reducing standby power.

In order to reduce such standby power, an outlet capable of reducing standby power has been developed. In the outlet that can cut off the standby power, the user can set the standby power to be cut off or continue to supply the power, or the amount of power serving as a standard to be determined as standby power is set through the input means. However, the outlet that can cut off the standby power is generally located in the corner or the back of the home or office that is not easily accessible from the user. Therefore, the outlet that can cut off the standby power can not effectively reduce the standby power. There is.

In addition, since an outlet capable of cutting off standby power only reduces the standby power of the electronics connected to the outlet, it is common to have a large number of outlets in a home or office, so to reduce standby power, all outlets provided with such standby power There is a problem that must be configured to have a function to block and the cumbersome problem that the user has to proceed with the operation, such as changing the settings of each outlet.

Therefore, there is a need for a system or device that is easily accessible to the user and can efficiently manage standby power of an outlet located in a home or office.

The present invention has been made in view of the above-described problems, it is possible to collectively reduce the power consumed in one or more connected outlets, and a standby power cut-off system and a standby switch for shutting off the combined power switch that can control one or more lights The purpose is to provide.

In addition, the purpose of the present invention is to provide a standby power cutoff system and a standby power cutoff composite switch that can reduce power consumption by reducing the amount of power consumed by the standby power cutoff composite switch.

In addition, by dynamically determining the standby power amount to determine that the standby power consumption of the outlet is being consumed by using the change in the power amount of the electrical appliance connected to the outlet, the standby power amount can be efficiently The purpose is to provide a standby power cut-off system and a composite switch for standby power cut-off.

In addition, in the existing standby power cut-off outlet where the user manually sets the standby power amount, it prevents the continuous standby power consumption that may be caused by the user's inexperienced operation and prevents malfunction such as the sudden turning off of the electronic product. The purpose is to provide a standby power cut-off system and a composite switch for standby power cut off.

It also aims to provide a standby power cut-off system with a user-friendly interface and a complex switch for standby power cut-off with a light-emitting diode that can adjust brightness according to external brightness and a reset signal when a reset signal is applied for a certain period of time. There is this.

The standby power cut-off system for achieving the above object is set to cut off or supply a first power switching unit that can be set to block or supply the first AC power supplied to the lamp and the second AC power output to the outlet. Display window for connecting the second power switching unit and the second power switching unit to measure the amount of current consumed by the second AC power supplied to the outlet and the amount of current measured from the current amount detecting unit as the amount of power; And an input unit for receiving a plurality of user input commands including a reset command from a user and a control unit for controlling the two power switching units based on the amount of current measured by the current amount detection unit, wherein the control unit includes: Consumption calculated based on the amount of current measured by the amount of current detector When the amount of power is equal to or less than the set reference standby power amount or more than the set reference overcurrent power amount, the second power switching unit is controlled to cut off the supply of a second AC power to the second power switching unit connected to the current amount detecting unit and the output unit And controlling the output unit to notify the user that the second AC power of the second power switching unit has been cut off, and when the input unit receives the reset command for a period of more than a threshold reset period, initializing the controller. do.

The composite switch for shutting off standby power for achieving the above object includes an outlet for supplying power to an electronic device through a terminal connected to a light outputting a light source, and standby power for controlling the power supply of the light and the outlet. And a cut-off device, wherein the standby power cut-off device includes: a first power switching unit capable of cutting off or supplying first AC power provided to the lamp; and blocking or supplying a second AC power provided to the outlet. A display window for displaying a current amount measured by the second power switching unit, a current amount detecting unit connected to the second power switching unit and measuring the amount of current consumed by the second AC power supplied to the outlet, and the current amount measured by the current amount detecting unit as electric power; Receiving a plurality of user input command including a reset command from the output unit and the user including a The second AC power supply is supplied to the second power switching unit connected to the current amount detecting unit when the power consumption calculated based on the current amount measured by the input unit and the current amount detecting unit is equal to or less than the set reference standby power amount or more than the set reference overcurrent power amount. And a control unit for controlling the output unit to notify the user that the second AC power of the second power switching unit has been cut off, and wherein the input unit receives the reset command for a period equal to or greater than a threshold reset period. In this case, the initialization of the controller is started.

The standby power cut-off system and the composite switch for standby power cutoff according to the present invention as described above have an advantage of managing the power consumption of the outlet and the lamp and the like, the integrated cutoff of the standby power.

In addition, there is an advantage that can significantly reduce the power consumed in the standby power cut-off system and the composite switch for standby power cut off.

In addition, it is possible to variably set the standby power that is the basis for power cutoff by identifying the change in the power amount of the connected outlet, so that even when an electronic device connected to the outlet changes or a new electronic product is added, Determining the power consumption due to the standby power cut off and the power consumption due to malfunction or inexperienced user's operation or inadequate setting caused by the change of the connected electronic products, and the user's inconvenience in using.

In addition, the brightness of the light emitting diodes attached to the standby power cut-off system and the standby power cut-off composite switch is dynamically changed according to the external brightness to provide a user-friendly interface.

1 is a configuration diagram illustrating an embodiment of a standby power cut-off system.
2 is a diagram illustrating an embodiment of a front surface of a composite switch for shutting down standby power capable of receiving a command from a user and displaying a status to the user.
3 is a block diagram showing a configuration of a composite switch for shutting off standby power.
4 is a block diagram illustrating an example of a configuration of a processor that implements a controller.
FIG. 5 is a view illustrating a power amount variation that changes with time at one outlet that may be connected to a composite switch for shutting off standby power.

Hereinafter, with reference to the accompanying drawings, preferred embodiments of the present invention will be described in detail. However, the spirit of the present invention is not limited to the embodiments in which the present invention is presented, and those skilled in the art who understand the spirit of the present invention may easily add other embodiments by adding, changing, deleting or adding components within the scope of the same idea. It may be suggested, but this will also fall within the scope of the spirit of the present invention.

1 is a configuration diagram illustrating an embodiment of a standby power cut-off system.

According to FIG. 1, the standby power cut-off system includes one or more outlets 2000, one or more lamps 3000, and a composite switch 1000 for standby power cutoff. In the present embodiment, two lamps ( 3000) and two outlets 2000 are shown.

The lamp 3000 may be turned on or off as power is supplied from an AC power source having a single line and connected or disconnected with one line under control of a power switch complex switch. The lamp 3000 may be a general incandescent bulb, a fluorescent lamp, or an LED lamp.

The outlet 2000 has two receiving terminals for receiving AC power, and has one or more connection ports having two connection terminals into which a plug such as an electronic product can be inserted to connect the AC power received from the receiving terminal. Provide AC power to connected electronics through The outlet 2000 may be a general outlet or an outlet having a standby power cutoff function.

The composite switch 1000 for standby power cut-off turns on or off the connected lamp 3000 according to the user's control, and cuts off or supplies the power to the connected outlet 2000 based on the user's control and the set standard standby power amount. Can supply In the present exemplary embodiment, the rear portion of the composite switch 1000 for standby power cutoff is illustrated. As shown in FIG. 1, a second AC power source having two lines supplied from a distribution panel and the like is a composite switch 1000 for standby power cutoff. Outlet connected to the composite switch 1000 for standby power is supplied to the composite switch 1000 for standby power cutoff through a connection terminal located at the rear of the control panel, and controls to connect or cut a line of one of the supplied second AC power sources. AC power may be cut off or supplied to 2000. In FIG. 1, only one line of the AC power is configured to be connected to the outlet 2000 from the composite switch 1000 for standby power cutoff, but both lines of the AC power are connected to the composite switch 1000 for standby power cutoff. It may be provided to the outlet 2000 and controlled to connect or disconnect both lines. On the other hand, the power for supplying the lamp 3000 is input from the distribution panel, one of the two lines of the first AC power input to the composite switch 1000 for standby power cut off, the received one line is again cut off the standby power Under the control of the composite switch 1000 for power is configured so that each of the lights 3000 may be supplied with power or cut off.

FIG. 2 is a diagram illustrating an embodiment of a front portion of a composite switch 1000 for shutting down standby power capable of receiving a command from a user and displaying a status to the user.

According to FIG. 2, the front portion of the standby power cut-off switch 1000 includes an input unit 1090 and an output unit 1110, and includes an illuminance detection sensor that can measure brightness of the remote control receiver 1120 and the outside. It may further include an illuminance detecting unit 1150 including. This example drawing is a front portion configured to correspond to the example configuration diagram of FIG. 1. Therefore, when the standby power cut-off system takes a different configuration of connection, the present exemplary front part may be different, and it may be obvious that even when the connection of the same configuration is adopted, it may take a different form depending on the user's input and output method and method. will be.

Referring to the method of operation of the user based on the exemplary diagram of FIG. 2, the user may use the standby button or the always button of the input unit 1090 to power each outlet 2000 connected to the composite switch 1000 for standby power cutoff. The power supply can always be supplied, or the power supply can be turned off immediately, or the power supply can be turned off when the power consumption is below the reference standby power. In addition, the user may view the power consumption of the currently selected outlet 2000 through the output unit 1110 in real time. In other words, the power display shows the current power consumption of a particular outlet in real time. In addition, the user may set the displayed amount of power currently being consumed by the selected outlet 2000 to the amount of power used as a reference for determining power supply interruption of the corresponding outlet 2000 by using a setting button or a standby button. Alternatively, by automatically detecting a change in the load amount of the outlet 2000, a reference standby power amount for determining a power supply interruption of the outlet 2000 may be automatically set. Meanwhile, the user may set the same command as the command input through the input unit 1090 using the remote controller. Detailed description of the configuration of the composite switch 1000 for standby power cut-off will be described below with reference to FIG. 3.

3 is a block diagram illustrating a configuration of a composite switch 1000 for shutting off standby power.

According to FIG. 3, the composite switch 1000 for standby power cutoff includes a first power input unit 1010, a second power input unit 1020, an SMPS 1030, a first power switching unit 1040, and a second power switching unit. 1050, the current amount detector 1060, the first power output unit 1070, the second power output unit 1080, the input unit 1090, the output unit 1110, the remote control receiver 1120, the communication unit 1130, A buzzer 1140, an illuminance sensor 1150, an external memory (not shown), a basic value setting unit 1160, and a controller 1170 are included. The block diagram of the composite switch 1000 for shutting down the standby power is shown as an embodiment, and some of these blocks may be omitted.

The first power input unit 1010 receives the power of one of the first AC power lines consisting of two lines received from the distribution panel and the like through, for example, a connection terminal located on the back of the composite switch 1000 for standby power cutoff. do. One line power source of the input first AC power source is provided to one or more first power source switching units.

The second power input unit 1020 receives a second AC power source from a distribution panel or the like. The input AC power is input through two lines or one line, and the input AC power is output to the second power switch 1050 and the SMPS 1030, and optionally, a second power that always outputs AC power. By directly outputting to an output unit (not shown), power can be always supplied without control of the controller 1170.

The SMPS 1030 converts the AC power supplied from the second power input unit 1020 into DC power for use in the controller 1170 and other blocks. The converted DC power source may be one DC power source or a plurality of DC power sources. For example, the SMPS 1030 may output 5V and 12V DC power supplies. In addition, the SMPS 1030 may include a protection circuit to prevent damage due to overcurrent from the supplied AC power, and the protection circuit may include a metal oxide varistor (MOV) or a fuse (FUSE).

The at least one first power switching unit 1040 is configured to supply or cut off the AC power of the disconnected wire to the first power output unit 1070. As illustrated in FIG. 3, the first power switching unit 1040 is configured to supply or cut off AC power of a single line according to the control of the controller 1170, or the user directly supplies or cuts off the control without the control of the controller 1170. For example, as shown in FIG. 2, the first power switching unit 1040 may be configured by using a switch. When controlled by the controller 1170, the first power switching unit 1040 may include a relay, a solid state relay (SSR), a silicon controlled rectifier (SCR), a trio for alternating current (TRIAC), a transistor (TR), or the like. It can be configured using an IGBT (Insulated Gate Bipolar Transistor).

The at least one second power switching unit 1050 controls the switching control signal output from the control unit 1170 to supply power of one line or both line powers of AC power supplied from the second power input unit 1020. According to output or disconnect. The second power switching unit 1050 may be configured using a relay, an SSR, an SCR, a TRIAC, a TR, or an IGBT.

Each of the one or more current amount detection units 1060 is connected to the corresponding second power switching unit 1050 and the second power output unit 1080, and consumed in the outlet 2000 connected via the second power output unit 1080. The amount of current to be detected is detected. The detected amount of current may be provided to the controller 1170 to be used by the controller 1170 to control the switching control signal from the amount of current consumed. The current amount detector 1060 may be a CT (Current Transform) or Shunt (SHUNT) method. By configuring, the amount of current can be detected.

The one or more first power output units 1070 output AC power supplied from the corresponding first power switching unit 1040. The first power output unit 1070 may supply or cut off power to the lamp 3000 through one connection terminal.

The one or more second power output units 1080 output AC power supplied from the corresponding second power switching unit 1050. The second power output unit 1080 may supply AC power to the outlet 2000 through two or one connection terminals.

The input unit 1090 sets a mode for each outlet 2000 of the composite switch 1000 for standby power cutoff by a user, for example, 'always power off' / 'always power supply' / 'standard standby power amount for each outlet. In the following, a user command such as 'power off' may be received, and may be configured as a touch type or a button type. The input signal from the input unit 1090 may include one or more signals, and the control unit 1170 may recognize a command having a different meaning from a user according to each input signal, an order between input signals, or a time order of the same input signal. You can run The signal received from the input unit 1090 may include a reset signal (reset command) for initializing the control unit 1170.

On the other hand, the reset signal received by the input unit 1090 is directly connected to the reset port of the processor constituting the control unit 1170 can be reinitialized immediately according to the reset signal, alternatively the reset signal is applied for a predetermined period After that, the controller 1170 may be initialized, for example, for 2 seconds. Alternatively, in order to configure the controller 1170 to be initialized only when a predetermined period of time (critical reset period) of the reset signal is applied, for example, a capacitor that charges or discharges in conjunction with a reset signal received from the input unit 1090 may be used. Configure. The controller may be configured to apply the charged or discharged reset signal to the reset port of the processor through an inverter again so that the processor is initialized only when the reset signal is continuously applied during the threshold reset period. That is, when the user touches or presses the reset button to reset the standby power cut-off outlet, the input reset signal charges or discharges the capacitor, and charges (eg, 0 to 5V) or discharges (eg, depending on the capacity of the capacitor). : Threshold level (e.g., Vth) where the speed of 5 to 0 V) can be adjusted, and the level of the corresponding charged or discharged power input to the inverter can change the value that the inverter outputs (e.g. 0, 5 V). ), The inverter can be inverted and configured to operate a signal that controls the processor's reset port, allowing the processor to initialize only if a reset signal has been input for more than a threshold reset period. With this configuration, even if the user accidentally touches a reset signal such as a button type or touch type, or even if it is not intended, the device immediately starts re-initialization upon application of the reset signal and temporarily turns the power to a connected outlet or lamp. Problems caused by blocking can be prevented. The threshold reset period can be calculated using the capacitance of the capacitor and the threshold level of the inverter. Of course, this critical reset period can be an error depending on the analog characteristics of the capacitor and inverter.

The output unit 1110 may include a light emitting diode such as one or more LEDs, and may include an LCD display (power display window) that can display the amount of power consumed by the outlet 2000 to the user. The output unit 1110 displays the state of the composite switch 1000 for standby power cutoff or a response to a command by a user, and may be installed to be adjacent to the same physical space as the input unit 1090, and the input signal is received. If so, it may be possible to show a direct response to that signal input.

On the other hand, the controller 1170 may be configured to control the current amount of the signal output to control the light emitting diode to adjust the brightness of the light emitting diode, for example, one or more controllers to the output signal to control the light emitting diode ( 1170 connects a selectable serial resistor. The controller 1170 is configured to apply a signal to only one of the series resistors selectable according to the external brightness sensed by the illuminance sensor 1150 (for example, by using a gate signal of a transistor). If the brightness is low, for example, the light emitting diode can be dark at night, and if the external brightness is bright, the light emitting diode is bright, so that the user can easily check the status of the standby power cut-off outlet through the light emitting diode. In addition, it is possible to prevent sleep disturbance due to high brightness of the light emitting diode at night.

In order to receive a user's command, the remote controller 1120 receives a remote controller signal transmitted from the outside and transmits the received remote controller signal to the controller 1170. The remote controller receiver 1120 may be configured as a remote controller sensor attached to the composite switch 1000 for shutting off standby power, as shown in the front of FIG. 2. The received remote control signal may be a signal output from, for example, a remote control of a TV or a DVD player used in general electronic products, or may be a signal output from a remote control dedicated for the composite switch 1000 for standby power cutoff.

The communication unit 1130 communicates with a central controller for controlling power supply / interruption of the home, for example, capable of communicating with the other standby power cut-off composite switch 1000 or the outlet 2000 or the standby power cut-off composite switch 1000. It is configured to. The communication method for communicating with an external device may be a wireless method such as power line communication, wired communication such as RS485, Zigbee, Bluetooth, or RF communication, and the communication unit 1130 may use one or more of the communication methods. Can be implemented. The communication unit 1130 and the control unit 1170 may communicate by connecting to a serial bus, for example, a serial bus such as UART, SPI, I2C, or the like, and a parallel bus used in the control unit 1170, and the communication unit 1130 may be wired or wireless. Receiving a control command received through the power line communication line, the control unit 1170 may control the second power switching unit 1050 to supply or cut power according to the control command, or used in the control unit 1170 The setting data related to the power supply of each outlet 2000 can be changed.

The buzzer 1140 is used to inform the internal state of the composite switch 1000 for shutting off the standby power under the control of the controller 1170 or to inform the response according to a user command. When the control unit 1170 applies the control signal to apply the buzzer sound, the buzzer 1140 is output while the control signal is applied, so that the buzzer 1140 may recognize the user according to a specific state or a response according to a user command.

The illuminance detector 1150 measures the brightness of the outside by using an illuminance detection sensor exposed to the outside in the composite switch 1000 for shutting off the standby power, and transmits the measured brightness of the outside to the controller 1170. The external brightness transmitted to the controller 1170 may be transmitted as an illuminance amount of an analog value or as an illuminance amount converted from an analog value to a digital value.

The external memory (not shown) is an additional block that can be used to store a program or data to be used by the controller 1170. The external memory may be composed of volatile memory or nonvolatile memory or a combination thereof.

The basic value setting unit 1160 may control the control unit 1170 or the standby power cut-off switch when the signal output from the control unit 1170 is not output or when there is no signal input to the signal input to the control unit 1170. It is possible to apply the signal as the basic signal value to prevent the malfunction 1000 and to operate at the default value. The basic value setting unit 1160 may be connected to a switching control signal output from the control unit 1170 or an output signal for the output unit 1110, and the control unit 1170 as in the case where the supply of power to the control unit 1170 is stopped. If the signal does not output a signal may be supplied to the value set by the basic value setting unit 1160. In addition, the basic value setting unit 1160 may be connected to a signal input from the input unit 1090, or may be connected to a remote control signal received from the remote control receiver 1120. The signal applied by the default value setting unit 1160 may vary depending on a default value to be set in the corresponding signal. For example, when power is supplied to the output of the second power switching unit 1050 when the switching control signal output from the control unit 1170 has a logic value of '1', the default value is set to '0'. When the control unit 1170 does not operate and the switching control signal is not output, the default value setting unit 1160 applies the default value of '0' so that power is not always output from the second power switching unit 1050. Do not. Alternatively, or vice versa, a switch capable of selecting '0' or '1' may be provided to allow the user to select the setting value. Likewise, a basic value of an input signal received through the input unit 1090 or the remote controller receiver 1120 may be set. If the input signal is a logic value '0', the controller 1170 recognizes that the signal is applied. The basic value setting unit 1160 is set to be the basic value with the value '1'. The basic value setting unit 1160 is configured to drive a basic value '1' or '0' by connecting to a resistor having a high resistance value and a driving power supply (VDD) or ground (GND) so that a low current flows. can do. In this way, the basic value setting unit 1160 is configured and connected to a switching control signal for controlling the second power switching unit 1050, so that even when the power supply is interrupted to some blocks in the processor implementing the control unit 1170, The setting can be maintained at a value such that the composite switch 1000 for shutting off standby power is normally operated while reducing power consumption of the processor.

The controller 1170 controls each block of the composite switch 1000 for blocking standby power. The controller 1170 may be implemented as a processor such as a central processing unit or a microcomputer or a microprocessor capable of reading and executing instructions such as 16 or 32 bit. The processor may further include one or more of blocks included in the composite switch 1000 for standby power cutoff. For example, the communication unit 1130 or the buzzer 1140 may be configured to be included. The processor may have at least two power management modes, and the processor may be configured according to a state of a switching control signal for the second power switching unit 1050 in the hybrid switch 1000 for standby power cutoff or a state setting according to a user command. A standby mode for power saving or a running mode for controlling each block of the composite switch 1000 for standby power cutoff may be transferred. The transition to the execution mode may be performed by applying a reset signal, and the transition from the execution mode to the standby mode may include all output signals (for example, a switching control signal or a signal of the output unit 1100) output from the controller 1170. May be configured to transition to the standby mode when is equal to a value that may be applied by the basic value setting unit 1160 connected to the corresponding output signal. One of the LEDs in the output unit 1100 for the standby mode may inform the user through the default value setting unit 1160 that the processor is in the standby mode. For example, the term standby mode or execution mode is used, but the spirit of the present invention may be applied to other terms to which the same concept may be applied. Standby mode refers to a state in which power consumption by the processor is reduced while power is cut off to at least one of the blocks constituting the processor. In the execution mode, power is supplied to a block in which power supply can be stopped. It means that the processor is operating normally. Meanwhile, the processor may receive a wake-up signal from an external block (for example, one signal or a reset signal from an input unit). The wake-up signal allows the processor to transition from the standby mode to the run mode. A detailed description of the processor implementing the controller 1170 will be described in detail with reference to FIG. 4.

4 is a block diagram illustrating an example of a configuration of a processor implementing the control unit 1170.

According to FIG. 4, a processor implementing the control unit 1170 includes a memory 1171, a GPIO interface unit 1172, an ADC unit 1173, an interrupt / reset receiving unit 1174, a power control unit 1177, and a CPU core 1179. It may further include a serial bus interface 1175, parallel bus interface 1176, LCD controller 1178.

The memory 1171 stores programs to be used in the CPU core 1179 of the processor, initialization programs to be used at boot, data to be used in the programs, and the like. The data to be used includes set data related to an outlet input by a user, and the memory 1171 may be configured as a nonvolatile memory or a combination of a nonvolatile memory and a volatile memory. Some of the programs can be stored in external memory.

The general purpose input output (GPIO) interface unit 1172 receives a 1-bit binary signal input from another block outside the processor or outputs a 1-bit binary signal. The received binary signal may be provided to the CPU core 1179 or stored in the memory 1171 via an internal control bus. The output binary signal is also output under the control of the CPU core 1179. For example, an input received from the input unit 1090 by outputting a switching control signal for controlling each of the second power switching unit 1050 or the first power switching unit 1040 through the GPIO interface unit 1172. A signal may be received, an output signal may be output to the output unit 1110, and a remote controller signal received from the remote controller receiver 1120 may be received.

The ADC unit 1173 converts an analog signal into a digital signal having a level of 1 bit or more, and stores the same in the memory 1171 or provides it to the CPU core 1179. When the digital signal to be converted is 8 bit, it can be converted to 256 levels, and the 16 bit digital signal can be converted to 65,536 levels. The ADC unit 1173 may receive a current amount detected by the current amount detector 1060 or an illuminance amount that is an external brightness received from the illuminance detector 1150 and convert the received amount to a digital level.

The interrupt / reset receiving unit 1174 receives the reset signal or the interrupt signal through the reset port or the interrupt port. The reset signal can also be seen as an interrupt signal. When the reset signal is received, the CPU core 1179 performs an initialization process, and when receiving an interrupt signal, is configured to notify the CPU core 1179 as an interrupt signal, and calls an interrupt handler according to the interrupt signal, Handle interrupts. At least one of the received interrupt signals may be used as a signal for the processor to switch from the standby mode to the run mode. The corresponding interrupt signal (wake-up signal) for switching from the standby mode to the run mode is configurable by the CPU core 1179. For example, if one of the input signals is connected to one interrupt signal as a wake-up signal, then when the signal is applied and the processor is in standby mode, the data or program start required to be released and stored in standby mode is released. You can switch back to normal execution mode by reloading the address.

The power control unit 1177 may supply or stop power to each block in the processor according to the control of the CPU core 1179 or the interrupt of the interrupt / reset receiving unit 1174. When the processor transitions to a normal execution mode that executes each block in the processor through a reset signal or an interrupt signal, each block is powered by the power control unit 1177 and each block is used for setting and controlling the CPU core 1179. Follow along. On the other hand, the power control unit 1177, according to the instruction of the program executed in the CPU core 1179, the ADC unit 1175, GPIO interface unit 1172, serial bus interface unit 1175, parallel bus interface unit 1176, The processor may switch to the standby mode by blocking at least one of power supplies provided to the LCD controller 1178 and the memory 1171. By shutting off the power supply in this way, the amount of power consumed by the processor itself can be reduced. In addition, the CPU core 1179 may set at least one of the received interrupt signals as a wake-up signal capable of switching the execution mode from the standby mode. The wake-up signal may be an input signal received from the input unit 1090. The remote controller may select from among remote controller signals received from the remote controller receiver 1120. When the corresponding wake-up signal is received, the CPU core 1179 may call the interrupt handler to set the power supply for the other blocks, the initialization progress for each block, and the data required for each block in the interrupt handler, thereby again returning to normal. You can maneuver. Of course, when the reset signal is applied, the power control unit 1177 supplies power to other blocks according to the initialization of the CPU core 1179.

The serial bus interface 1175 may communicate with a serial bus such as UART, SPI, I2C, or the like. The serial bus interface unit 1175 communicates with the communication unit 1130 external to the processor to perform network setup and data transmission and reception through the communication unit 1130, and to measure the amount of illuminance measured by the illumination detection unit 1150. The current detection amount of the current detection unit may be received through the serial bus interface unit 1175.

The parallel bus interface unit 1176 is a bus interface capable of simultaneously transmitting and receiving data of 8 bits, 16 bits, or more. Examples of parallel buses may include a bus interface of volatile memory such as SDRAM / DDR DRAM, an Intel or Motorola bus type, or a PCI or IDE bus.

The LCD controller 1178 may periodically or aperiodically provide an image or the like to an LCD display (display window) that may be included in the output unit 1110. The LCD controller 1178 periodically reads an image (frame) included in the memory 1171 or an external memory, periodically provides an image to the LCD display, and displays information on the LCD display. Information displayed includes the amount of power from the amount of current measured by the amount of current detector, the connection or disconnection status of the power switching unit, and the like. In addition to the LCD display, it may include a black and white dot matrix type LCD and a color LCD.

The CPU core 1179 reads a program from the memory 1171 or an external memory to control each block in the processor. The CPU core 1179 can be set to serve as a wake-up signal by one of the interrupt signals by the program, and the CPU core 1179 designates a specific area stored in the memory 1171 as an area for the interrupt handler, When the interrupt signal including the wake-up signal is applied, the corresponding interrupt handler enables the program to be executed in response to the interrupt signal.

In the above, the structure of the standby power cut-off system and the composite switch 1000 for standby power cut-off have been described in detail. Hereinafter, an embodiment performed by the controller 1170 will be described based on various methods of setting a reference standby power amount that can be used by the controller 1170. The controller 1170 controls the lamp 3000 or the outlet 2000 connected to the composite switch 1000 for standby power cutoff according to a user's command through the input unit 1090. For each outlet there may be several modes that the user can set through the input 1090. For example, for each outlet, it can have an always-on power supply mode that can always be powered on, an always-power off mode that can always be powered off, and conditionally the amount of power consumed at the outlet is below the reference standby power. When the power is cut off, and if the reference standby power is greater than the condition may have a conditional power supply mode for supplying power. In the conditional power supply mode, in order to detect the amount of power consumed by the outlet, at a predetermined period (for example, 1 second) from the current amount detector 1060 connected to the second power output unit 1080 that outputs power to the outlet. The controller 1170 receives the detected current amount. The received current amount is converted into a power amount again and compared with the reference standby power amount, and if it is less than the reference standby power amount, it is output to the second power switching unit 1050 which controls the corresponding outlet after a certain period (for example, 90 seconds). The switching control signal is set so that the power supply is cut off. The current received in this process may be periodically averaged and compared with the reference standby power in the averaged current. In addition, the controller 1170 compares the amount of overcurrent power that can flow in the connected outlet 2000 with the amount of power calculated from the amount of current detected by the amount of current detection unit 1060, and when the amount of overcurrent power is greater than or equal to supply or cut off AC power to the outlet. By controlling the second power switch 1050 to be blocked, it is possible to prevent a fire due to overcurrent. When the switching control signal output to the two power switching unit 1050 is set such that the power supply is cut off, the user may be notified through the output unit 1110 or the buzzer 1140.

The reference standby power used in the conditional power supply mode in the controller 1170 may be calculated in several ways. First, a method of setting a reference standby power amount by the user's involvement, second, a method of setting using the illuminance sensor 1150, and third, a change in the amount of current detected by the current amount detector 1060 as shown in FIG. A method of setting a reference standby power amount using a trend. In addition, when power line communication is possible in an electronic product connected to the outlet 2000, the standby power may be directly received from the electronic product through power line communication. In addition, the composite switch 1000 for standby power cutoff may have a reference standby power amount set at the time of initial production as a default value, and may be set to a value such as 10 W or 20 W, for example. You can also use this default as the reference standby power.

First, a method of setting the reference standby power amount under the user's standby power setting command through the input unit 1090 will be described. The electronic device to be used is connected to the outlet 2000 to set the reference standby power amount. The electronic product is turned off while being connected to the outlet 2000 by using the power key of the remote control of the electronic product or the power button of the electronic product, such that the electronic product is in the standby mode. Then, the user measures a current amount of the corresponding outlet through the input unit 1090 of the composite switch 1000 for standby power cutoff, and sets a button or the like to set the power amount calculated from the measured current amount as the reference standby power amount to be used by the controller 1170. By using the command, the controller 1170 may output the set reference standby power amount through the output unit 1110 so that the user can check the set reference standby power amount.

Secondly, the setting method using the illuminance sensor 1150 is based on the fact that it is common for a user to set an electronic product to a standby mode using a power key at night. By selecting through the input unit 1090 of the reference standby power can be set in this way. In the method of setting the reference standby power amount through the illuminance sensor 1150, the controller 1170 checks the illuminance amount through the illuminance sensor 1150. The amount of current consumed by the outlet 2000 is received from the current amount detector 1060 only when the amount of illuminance is equal to or less than a threshold illuminance (eg, a dark situation such as 100 cd). The controller 1170 periodically receives the amount of current, calculates the amount of power from the received amount of current, and finds the lowest amount of power below the threshold illuminance. The lowest amount of power found is again compared to the current reference standby power amount (the previously set reference standby power amount). If the found power amount is higher than the current reference standby power amount, the value of the found power amount is replaced. This has the advantage of preventing the leakage of standby power. In addition to this method, the reference standby power amount can be set by further using the conversion trend of the current amount.

 Third, as shown in FIG. 5, the reference standby power amount is set using the change in the amount of current detected by the current amount detector 1060. One or more electronic products may be connected to the outlet 2000 connected to the composite switch 1000 for standby power cutoff. Each electronic product has a constant trend in power consumption as it is used. For example, during the period (a), one electronic product goes through the initial stage of starting up (e.g., turning on the TV by receiving a power key), and generally performing the functions of the electronic product (TV The program is displayed on a specific channel), and the electronics are in the standby phase (using the remote to power off the TV). Initially, the reference standby power amount may be the case where there is no setting. Or it may be a predetermined reference standby power amount. In the change trend such as (a), the difference in the amount of power in the initial stage or the function execution stage and the standby stage may be up to 10 times or more. Of course, there may be a difference of less than that, but since the difference in the amount of power in the function performing stage and the standby stage is significant and the ratio is significantly different, it is possible to easily set a threshold difference or a threshold difference ratio that separates any two stages. . This threshold difference or threshold difference ratio may be used to identify the waiting stage. In addition, it can be seen that the initial stage or the function execution stage starts from the standby stage or after the power cut, and consumes the maximum amount of power or the amount of power close to the maximum value. Although the initial stage and the functional performance stage have been separately described, the two stages may be recognized as one stage. In step (a), when the transition from the function performing step to the standby step is performed, the controller 1170 compares the currently set reference standby power amount with the power amount in the standby step, and if the reference standby power amount is less than the power amount in the standby step The current power amount in the standby step is set to be the reference standby power amount. The second power switch 1050 may be controlled to cut off power. Step (b) shows the transition of the step of the same electronic product, so there is no change in the reference standby power. Step (c) shows an initial step and a function performing step of the same electronic product as in (a) or (b). However, in step (d), other electronic products are connected to the same outlet 2000 to enter an initial stage, a function performing stage, and a standby stage, and then the two electronic products enter the standby stage in the same manner. Looking at step (d) in more detail, two electronic products perform a function, such that the electronics used in steps (a) and (b) begin to function first, and then other electronics begin to function. Only electronics enters the standby phase first. The amount of power consumed at this point, of course, is at least higher than the amount of power consumed in the first product's functioning phase by the electronics that are functioning first, so not all of the electronics connected to the outlet 2000 are on standby. It can be seen. This can be remembered by storing power consumption at each stage or by storing it at regular intervals. And finally, both electronics enter standby. In this case as well, the amount of power consumption at the stage of the change in the amount of power consumption, for example, the maximum amount of power consumed (for example, the amount of power consumed by the two electronics functioning) or the amount of power consumed at the stage of functioning of the electronic product that caused the maximum value. Alternatively, the difference in ratio may be compared to find that all connected electronic products are in the waiting stage when the difference in magnitude or ratio is greater than or equal to the threshold difference or the threshold difference ratio. Then compare the existing reference standby power with the current standby power. Since the existing standby power amount is for one electronic product used in the steps (a) and (b), it will of course be less than the current standby state of the two electronic products. Therefore, the amount of power in the current standby phase may be changed back to the reference standby power amount, and the power may be set to be cut off from the second power switch 1050 connected to the outlet 2000. Such an exemplary method according to the change of power amount may have various changes, and this change embodiment may be easily changed and applied by storing and analyzing the change of power amount in each step, especially from one power off. It is possible.

Of course, the reference standby power amount set may be set to be equal to or larger than the standby power amount calculated from the measured current amount.

Meanwhile, the controller 1170 may also receive a remote controller signal, and the received remote controller signal may be a signal transmitted from a remote controller used in another home appliance. The signal transmitted from the remote controller of another product may be, for example, a signal representing a power key, and when the power key is received, the controller 1170 may be configured to supply power to an outlet from which power is cut off. The remote control code value may be stored in the memory 1171 or the like, or the remote control code value may be immediately recognized and stored through the remote control receiver 1120 and used in the future. In addition, the controller 1170 may set a communication ID to be used by the communication unit 1130. In the method of setting a communication ID, the communication ID is set by the user's command received through the input unit 1090 (for example, by using a user's button input or by selecting one of the available communication IDs using a switch) or by manufacturing. It may be set to a communication ID determined at the time, or a communication ID for communicating with the outside using a numeric key on a remote controller of another electronic product. For this purpose, the code value of a specific remote control is stored in advance, or the user's remote control setting command, etc., remembers the numeric keys of the remote control received from the electronic product, and receives the numeric keys using the corresponding numeric keys to set the communication ID. (1130).

The present invention described above is capable of various substitutions, modifications, and changes without departing from the technical spirit of the present invention for those skilled in the art to which the present invention pertains. It is not limited by the drawings.

1000: composite switch for standby power cutoff 1010: first power input unit
1020: second power input unit 1030: SMPS
1040: first power switching unit 1050: second power switching unit
1060: current amount detection unit 1070: first power output unit
1080: second power output unit 1090: input unit
1110: output unit 1120: remote control receiver
1130: communication unit 1140: buzzer
1150: illuminance detection unit 1160: basic value setting unit
1170: control unit 1171: memory
1172: GPIO interface unit 1173: ADC unit
1174: interrupt / reset receiving unit 1175: serial bus interface unit
1176: parallel bus interface unit 1177: power control unit
1178: LCD controller 1179: CPU core
2000: outlet 3000: light fixture

Claims (11)

As a composite switch for standby power cutoff,
A first power switch configured to block or supply a first AC power supplied to the lamp;
A second power switch configured to block or supply a second AC power output to an outlet;
A current amount detector connected to the second power switch to measure an amount of current consumed by the second AC power provided to the outlet;
A memory for periodically storing the amount of current measured by the amount of current detector to identify a variation pattern of power consumption of the outlet;
An output unit including a display window for displaying the amount of current measured by the amount of current detection unit as the amount of power;
An input unit configured to receive a plurality of user input commands including a reset command from a user; And
A control unit controlling the second power switching unit based on the amount of current measured by the current amount detecting unit;
Including;
The controller may be configured such that when the amount of power consumption calculated based on the amount of current measured by the amount of current detector is equal to or less than the set reference standby power amount or equal to or more than the set reference overcurrent power amount, Controlling the second power switching unit to cut off the supply and controlling the output unit to notify the user that the second AC power of the second power switching unit is cut off at the output unit,
The control unit may identify a variation pattern of the power consumption of the outlet from the amount of current periodically stored in the memory, identify a performance stage and a standby stage of the outlet from the identified variation pattern, and store the amount of current corresponding to the identified standby stage. Set the reference standby power amount based on;
When the input unit receives the reset command for a period of more than a threshold reset period, characterized in that the initialization of the control unit starts,
Composite switch for standby power off. The method of claim 1,
The control unit changes the reference standby power amount based on the current amount measured by the current amount detection unit according to the standby power setting command received from the input unit, and the output unit displays the changed reference standby power amount,
Composite switch for standby power off. delete The method of claim 1,
It further includes an SMPS for converting AC power into DC power,
The plurality of user input commands received by the input unit are received using a plurality of signals,
The control unit is implemented as a processor, and when the power of the second power switching unit is cut off, the processor supplies power to some blocks constituting the processor to reduce the current consumption supplied from the DC power. And a signal of one of the plurality of signals is connected to a reset port or an interrupt port of the processor such that when the one signal is applied, the processor reapplies power to the part of the block where power supply is interrupted. Characterized by
Composite switch for standby power off. The method of claim 1,
It further comprises an illuminance sensor for measuring the external brightness to output the external brightness measured by the control unit,
The output unit further includes at least one LED that can indicate the state of the composite switch for standby power cut off,
The controller may adjust the brightness of the LED according to the external brightness received from the illuminance sensor,
Composite switch for standby power off. The method of claim 1,
Further comprising a communication unit capable of performing at least one communication of power line communication, wireless communication and wired communication,
The control unit controls the second power switching unit according to a control command received from the communication unit,
Composite switch for standby power off. The method of claim 6,
Further comprising a remote control receiver for receiving a remote control signal,
The control unit may set a communication ID to be used in the communication unit from a remote control signal received from the remote control receiver or a user input command received from the input unit.
Composite switch for standby power off. Standby power cut off system,
An electric light outputting a light source;
An outlet for supplying power to the electronic device through the connected terminal; And
It includes a standby power cut-off device that can control the power supply of the light and the outlet,
The standby power blocking device,
A first power switching unit capable of interrupting or supplying a first AC power provided to the lamp;
A second power switching unit capable of interrupting or supplying a second AC power provided to the outlet;
A current amount detector connected to the second power switch to measure an amount of current consumed by a second AC power provided to the outlet;
A memory for periodically storing the amount of current measured by the amount of current detector to identify a variation pattern of the amount of power consumption of the outlet;
An output unit including a display window for displaying the amount of current measured by the amount of current detection unit as the amount of power;
An input unit for receiving a plurality of user input commands including a reset command from a user;
When the amount of power consumption calculated based on the amount of current measured by the current amount detection unit is less than the set reference standby power amount or more than the set reference overcurrent power amount, the supply of the second AC power to the second power switching unit connected to the current amount detection unit is cut off And a controller configured to control the output unit to inform the user that the second AC power of the second power switch is cut off.
The control unit may identify a variation pattern of the power consumption of the outlet from the amount of current periodically stored in the memory, identify a performance stage and a standby stage of the outlet from the identified variation pattern, and store the amount of current corresponding to the identified standby stage. Set the reference standby power amount based on;
When the input unit receives the reset command for a period of more than a threshold reset period, characterized in that the initialization of the control unit starts,
Standby Power Shutdown System. The method of claim 8,
The control unit may change the reference standby power amount based on the current amount measured by the current amount detection unit or change the predetermined reference standby power amount according to the standby power setting command received from the input unit.
Standby Power Shutdown System. The method of claim 8,
The standby power cut-off device further includes an illuminance sensing unit measuring an external brightness and outputting the external brightness measured by the controller,
The output unit further includes at least one LED that can indicate the state of the standby power cutoff device,
The controller may adjust the brightness of the LED according to the external brightness received from the illuminance sensor,
Standby Power Shutdown System. The method of claim 8,
The standby power cut-off device further includes a communication unit capable of performing at least one communication among power line communication, wireless communication, and wired communication, and a remote control receiver capable of receiving a remote control signal.
The control unit may set a communication ID to be used in the communication unit from a remote control signal received from the remote control receiver or a user input command received from the input unit.
Standby Power Shutdown System.

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