KR100974823B1 - Apparatus for reducing standby power consumption - Google Patents

Abstract

The present invention relates to an apparatus and a method for reducing standby power.

The standby power saving device of the present invention disposes a latching relay that consumes current only during initial operation and does not consume current after maintaining a contact point between a power input terminal and a first power supply in standby and a second power supply in driving. In accordance with the control signal, the latching relay contacts the first power supply or the second power supply so that power is applied from the power input to the first power supply or the second power supply.

Therefore, since the latching relay is used, when the conventional relay is used, the power consumed while the relay maintains the contact point can be reduced, and thus standby power can be further reduced than before, and in the driving mode of the electronic product, the standby power is completely shut off. In the driving mode, standby power can be further reduced as compared with the conventional standby power consumption.

Standby power, savings, latching relay, control unit, remote control, current status

Description

Standby power saving device {Apparatus for reducing standby power consumption}

The present invention relates to an apparatus and a method for reducing standby power, and more particularly, to an apparatus and a method for reducing standby power of an electronic product using a latching relay.

Recently, electronic products equipped with various advanced functions are rapidly spreading at homes and workplaces. In particular, household appliances such as electronic appliances with memory functions such as time and operation schedules, such as electric rice cookers, microwave ovens, refrigerators, etc., and electronic appliances with memory functions and remote control functions, such as TVs, audio, video, and air conditioners It is widely used in. An electronic product having a remote control function must always supply power to operate a remote controller, that is, a remote controller, and always supply power to implement a memory function. Therefore, in order to reduce power consumption, the user must take the inconvenience of disconnecting the power by disconnecting the electronic product whenever the home appliance is not in use. However, electronic products with a memory function lose all memory functions when the power supply is cut off. Therefore, an electronic product having a memory function consumes power even when not in use. The power consumed to maintain the memory function or the remote control reception state when the electronic product is not used is called standby power. The standby power varies depending on the electronic product, but usually 4 to 10 Watts are consumed. However, such standby power consumption may occur even in the case of an electronic product having no memory function, for example, a washing machine, which occurs when a user uses the plug while being plugged into an outlet.

As such, in order to reduce standby power consumed by an electronic product, a logic circuit may be employed to operate according to whether a reservation is made, whether a reservation time or a reservation time has elapsed. However, in this case, the standby power can be reduced locally and locally, but there is a problem that the standby power can not be significantly reduced because the logic circuit consumes standby power when the electronic product is not in use.

In addition, Korean Patent Publication No. 2004-0020344 (name of the invention: a power saving device for reducing standby power consumption of home appliances) has been proposed as another method for reducing standby power. The prior art uses a relay and allows the relay to make contact with a second transformer that supplies power when the TV is in use. However, the prior art consumes power while the contact of the relay moves and while the relay maintains the contact. In addition, standby power continues to be consumed even when the TV is in use. Therefore, standby power consumption cannot be reduced.

The present invention provides a standby power saving device and method that can reduce the standby power of electronic products by using a latching relay that consumes current only while the contact moves and does not consume current after maintaining the contact.

According to the present invention, a latching relay is disposed between a power input stage and a standby first power supply and a second power supply during driving, and the latching relay controls the power supply of the first power supply and the second power supply to drive electronic products. The present invention provides a standby power saving device and method that can completely cut off standby power.

The present invention provides a standby power saving device and method that can be applied to not only electronic products having a remote control function using a latching relay, but also passive electronic products or multi taps.

Standby power saving apparatus according to an aspect of the present invention includes a power input unit; First and second power supply units connected to the power input unit and generating and supplying a first power source and a second power source, respectively; A control unit receiving a control signal according to the current state of the standby mode or the driving mode; And a latching relay that moves a contact according to an output signal of the controller to control a connection between the power input unit and the first and second power supplies.

The apparatus may further include a control signal input unit configured to input the control signal generated by a user's remote controller and transmit the control signal to the controller.

And a switch for generating the control signal by an on / off operation of a user.

The controller may include a first controller configured to input the control signal when the current state is a standby mode; And a second controller for inputting the control signal when the current state is a driving mode.

The first control unit moves the contact of the latching relay to the second power supply unit so that the power input unit and the second power supply unit are connected, and the second control unit moves the contact of the latching relay to the first power supply unit. Move to allow the power input and the first power supply to be connected.

The first power is supplied to the first control unit, and the second power is supplied to the second control unit.

The latching relay consumes current while the contact moves and does not consume current while maintaining the contact.

According to an aspect of the present invention, there is provided a method for reducing standby power, comprising: initializing a contact of a latching relay to a first position by applying power; Generating a second power source for operating in a driving mode by moving a contact of the latching relay to a second position when the current state is a standby mode according to a control signal; And generating a first power source for operating in the standby mode by moving the contact of the latching relay to the first position when the current state is the driving mode according to the control signal.

According to another aspect of the present invention, a method for reducing standby power may include a switch; A power input unit configured to input AC power according to the driving of the switch; A power supply unit configured to receive the AC power and generate and supply driving power; A controller for detecting an end of the operation and outputting a control signal; And a latching relay that moves a contact according to the switch or the control signal to control a connection of the power input unit and the power supply unit.

According to another aspect of the present invention, a method for reducing standby power may include a switch; A power input unit configured to input power according to the driving of the switch; A power output unit configured to output power input through the power input unit; A current sensing unit sensing a current level between the power input unit and the power output unit; A control unit outputting a control signal according to the output signal of the current sensing unit; And a latching relay configured to control a connection of the power input unit and the power output unit by moving a contact according to the switch or the control signal.

The current detector generates a detection signal when the current level is less than or equal to the set level.

According to the present invention, a standby power saving apparatus is configured by using a latching relay that consumes current only during initial operation and does not consume current after maintaining a contact point. The latching relay is arranged between the power input terminal and the standby first power supply and the second power supply during driving, and according to the control signal, the latching relay makes contact with the first power supply or the second power supply to supply power from the power input. To be applied to either the first power supply or the second power supply. In addition, the standby power saving device using the latching relay can be applied not only to electronic products having a remote control function but also to passive electronic products or multi taps.

Therefore, since the latching relay is used, when the conventional relay is used, the power consumed while the relay maintains the contact can be reduced, and thus standby power can be further reduced.

In addition, since the standby power is completely blocked in the driving mode of the electronic product, standby power may be further reduced as compared with the conventional method in which standby power is consumed even in the driving mode.

Hereinafter, with reference to the accompanying drawings will be described an embodiment of the present invention; However, the present invention is not limited to the embodiments disclosed below, but may be implemented in various forms, and only the embodiments are intended to complete the disclosure of the present invention and to those skilled in the art. It is provided for complete information.

1 is a block diagram illustrating a configuration of a standby power saving apparatus according to an embodiment of the present invention, a configuration diagram of a standby power saving apparatus used in an electronic product having a remote control function.

Referring to FIG. 1, the standby power saving apparatus according to an exemplary embodiment may include a power input unit 110, a control signal input unit 120, a first control unit 130, a second control unit 140, and a first power supply unit. 150, the second power supply 160, and the latching relay 170.

The power input unit 110 is connected to, for example, an AC power supply terminal for supplying an AC voltage of 220V, for example, an outlet, and receives an AC voltage. The power input unit 110 may be, for example, a plug.

The control signal input unit 120 receives a control signal from a remote controller and transmits a control signal to the first control unit 130 or the second control unit 140 according to the current state of the electronic product. That is, the control signal input unit 120 transmits a control signal input from the remote controller to the first controller 130 when the current electronic product is in the standby mode, and removes a control signal input from the remote controller when the current electronic product is in the driving mode. 2 to the control unit 140. The control signal input unit 120 alternately transfers the control signal input from the remote controller to the first control unit 130 and the second control unit 140. First, after the power is connected to the electronic product, the first control signal input from the remote controller is transmitted to the first controller 130 so that the electronic product is in a driving mode, and the control signal input from the remote controller in the driving mode of the electronic product is second. The control unit 140 transmits the electronic device to the standby mode.

The first control unit 130 is driven by the first power supplied from the first power supply unit 150, and drives the latching relay unit 170 in response to the control signal input from the control signal input unit 120. That is, the first control unit 130 latches the second power supply unit 160 and the power input unit 110 in response to a control signal input from the control signal input unit 120 when the current state of the electronic product is in the standby mode. The relay 170 is controlled.

The second control unit 140 is driven by the second power supplied from the second power supply unit 160, and drives the latching relay unit 170 in response to the control signal input from the control signal input unit 120. That is, the second control unit 140 latches the first power supply unit 150 and the power input unit 110 in response to the control signal input from the control signal input unit 120 when the current state of the electronic product is the driving mode. The relay 170 is controlled.

The first power supply unit 150 is connected to the power input unit 110 through a latching relay 170 through which the contact is moved under the control of the second control unit 140, and the electronic product is required to maintain the standby mode. 1 Generate power. The first power generated by the first power supply unit 150 is supplied to the first control unit 130 so that the first control unit 130 is in a standby state for receiving a control signal, and is supplied to the memory unit of the electronic product to supply the electronic product. Its advanced features ensure normal operation even after the main power is turned off.

The second power supply unit 160 is connected to the power supply unit 110 through a latching relay 170 through which the contact is moved under the control of the first control unit 130, and the electronic product is required to maintain the driving mode. 2 Generate power. Here, the second power source is generated at a higher level than the first power source. The second power generated by the second power supply unit 160 is supplied to the second control unit 140 so that the second control unit 140 is ready to receive a control signal, and is supplied to the driving unit of the electronic product to supply the electronic product. Keep the drive mode.

The latching relay 170 is disposed between the power input unit 110, the first power supply 150, and the second power supply 160. The latching relay 170 receives a control signal from the first control unit 130 or the second control unit 140, and controls the contact point between the first power supply unit 150 and the second power supply unit 160 in response thereto. . That is, when the latching relay 170 receives a control signal from the first control unit 130, the latching relay 170 sets a contact point between the second power supply unit 160 and the power input unit 110. In addition, the latching relay 170 sets a contact point of the first power supply unit 150 and the power input unit 110 in response to receiving the control signal from the second control unit 140. At this time, the latching relay 170 consumes a current at the moment it is moved to form a contact, but does not consume a current after forming the contact. Therefore, the consumption of standby power can be reduced.

2 is a flowchart illustrating a standby power saving method using the standby power saving apparatus according to an embodiment of the present invention.

S110: For example, the power input unit 120 is connected to an AC power supply terminal for supplying an AC voltage of 220V, that is, an outlet to receive an AC voltage. When the AC power is input from the power input unit 120 as described above, the contact of the latching relay 170 is initialized. The contact of the latching relay 170 moves to the first power supply unit 150 and the power input unit 120 and the first power source. Supply unit 150 is connected. Therefore, the first power supply unit 150 generates the first power, and supplies it to the first control unit 130 so that the first control unit 130 is in a standby state for receiving the control signal. In addition, the first power generated from the first power supply unit 150 is supplied to the memory of the electronic product to perform the memory function of the electronic product.

S120: Then the control signal input unit 120 inputs a control signal output from the remote control.

S130: The control signal input from the remote controller is input to the control signal input unit 120, and the control signal input unit 120 transmits the control signal to the first control unit 130 or the second control unit 140 according to the current state of the electronic product. To pass.

S140: Since the current state of the electronic product is in the standby mode after power is supplied to the electronic product, the control signal input from the remote control becomes a control signal for maintaining the electronic product in the driving mode. Therefore, the control signal input unit 120 transmits the control signal to the first control unit 130. The first controller 130 controls the latching relay 170 to move the contact of the latching relay 170 to the second power supply 160 in response to the control signal. That is, the first control unit 130 pushes the latching relay 170 holding the contact with the first power supply unit 150 to move the contact of the latching relay 170 to the second power supply unit 160. Accordingly, the power input unit 120 and the second power supply unit 160 are connected to input power to the second power supply unit 160. The second power supply unit 160 generates a second power supply and supplies it to the second control unit 140 so that the second control unit 140 is ready to receive a control signal. In addition, the second power generated from the second power supply 160 is supplied to the driver for the operation of the electronic product. The second power supply may be partially supplied to the memory unit to perform a memory function of the electronic product.

S150: The control signal input from the remote control while the electronic product maintains the driving mode becomes a control signal for maintaining the electronic product in the standby mode. Therefore, the control signal input unit 120 transmits the control signal to the second control unit 140. The second control unit 120 controls the latching relay 170 to push the contact of the latching relay 170 in response to the control signal so that the contact of the latching relay 170 is moved to the first power supply 150. Therefore, the power input unit 120 and the first power supply unit 150 are connected to input power to the first power supply unit 150. The first power supply unit 150 generates the first power and supplies the same to the first controller 130 so that the first controller 130 is in a standby state for receiving a control signal. In addition, the first power generated from the first power supply unit 150 is supplied to the memory of the electronic product to perform the memory function of the electronic product.

The control signal input to the control signal input unit 120 is transferred to the first control unit 130 or the second control unit 140 according to the current state of the electronic product, and the subsequent steps are repeated. That is, when the electronic product is in the standby mode, the control signal is transmitted to the first control unit 130, and when the electronic product is in the driving mode, the control signal is transmitted to the second control unit 140. In addition, the first control unit 130 pushes the contact of the latching relay 170 to connect the power input unit 110 and the second power supply unit 160 so that the electronic product is in a driving mode, and the second control unit 140. Pushes the contact of the latching relay to connect the power input unit 110 and the first power supply unit 150 so that the electronic product is in a standby mode.

One embodiment of the present invention has been described with respect to the standby power saving device using a latching relay used in electronic products having a memory function and a remote control function. However, when the control signal input unit 20 is not provided, a standby power saving device using a latching relay may be used for a passive product having a memory function. For example, if a switch is provided in place of the control signal input unit 20 and the on / off of the switch is sensed and the first control unit 30 and the second control unit 40 are driven to be used in a passive electronic product having a memory function. Can be.

In addition, in the standby power saving apparatus using the latching relay, not only an electronic product having the memory function but a washing machine or the like having no memory function may be used for the passive electronic product or the multi-tap. Hereinafter, a standby power saving apparatus used for a manually operated electronic product and a multi tap will be described.

3 is a block diagram illustrating a configuration of a standby power saving apparatus according to another embodiment of the present invention, which is a block diagram of a standby power saving apparatus used for an electronic product which is operated manually without a memory function.

Referring to FIG. 3, the standby power saving apparatus according to another embodiment of the present invention includes a power input unit 110, a switch 220, a latching relay 170, a power supply unit 230, and a controller 240.

The power input unit 110 is connected to, for example, an AC power supply terminal for supplying an AC voltage of 220V, for example, an outlet, and receives an AC voltage. The power input unit 110 may be, for example, a plug.

The switch 220 moves the contact of the latching relay 230 to drive the passive electronic product so that the power input 110 and the power supply 240 are connected.

The latching relay unit 170 is disposed between the power input unit 110, the switch 220, and the power supply unit 230. The latching relay unit 170 moves the contact point by driving the switch 220 of the user so that the power input unit 110 and the power supply unit 230 are connected. In addition, the latching relay 170 moves the contact in response to the control signal of the control unit 240 to move the contact of the latching relay 170 toward the switch 220. That is, the latching relay 170 moves the contact point so that the power input unit 110 and the power supply unit 230 are connected by the operation of the switch 220 of the user during the operation of the passive electronic product, and the control unit (at the end of the operation of the passive electronic product) The contact of the latching relay 170 is moved toward the switch 220 according to the control signal of 240. At this time, the latching relay 170 consumes a current at the moment it is moved to form a contact, but does not consume a current after forming the contact. Therefore, the consumption of standby power can be reduced.

The power supply 230 is connected to the power supply 110 through a latching relay 170 in which a contact is moved according to the driving of the switch 220 of the user, thereby generating power required for the passive electronics to maintain an operating state. do. Power generated by the power supply 230 is supplied to the controller 240 and the driver of the electronic product to maintain the driving mode of the electronic product.

The controller 240 is driven according to the power generated by the power supply 230, and counts the set operating time of the passive electronic product to generate a control signal after the set operating time ends. The control signal generated by the control unit 240 is transmitted to the latching relay 170, the latching relay 170 receives the control signal to move the contact point from the power supply 230 to the switch 220.

4 is a block diagram illustrating a configuration of a standby power saving apparatus according to another embodiment of the present invention, and is a block diagram of a standby power saving apparatus used for a multi tap.

Referring to FIG. 4, the standby power saving apparatus according to another embodiment of the present invention may include a power input unit 110, a switch 220, a latching relay 330, a current sensing unit 340, a controller 320, and a power source. An output unit 360 is included.

The power input unit 110 is connected to, for example, an AC power supply for supplying an AC voltage of 220V, for example, an outlet, and receives an AC voltage. The power input unit 110 may be, for example, a plug.

The switch 220 moves the contact of the latching relay 230 to drive the multi-tap so that the power input unit 110 and the current sensing unit 310 are connected.

The latching relay 170 is disposed between the power input unit 110, the switch 220, and the current sensing unit 310. The latching relay 170 moves the contact point by driving the switch 220 of the user so that the power input unit 110 and the current sensing unit 310 are connected. In addition, the latching relay 170 allows the contact of the latching relay 170 to move toward the switch 220 in response to the control signal of the controller 320. That is, the latching relay 170 moves the contact point so that the power input unit 110 and the current sensing unit 310 are connected by the operation of the switch 220 of the user, and the latching relay 170 according to the control signal of the controller 320. ) Is moved to the switch 220 side. At this time, the latching relay 170 consumes a current at the moment it is moved to form a contact, but does not consume a current after forming the contact. Therefore, the consumption of standby power can be reduced.

The power output unit 330 includes at least one or more outlets configured in the multi-tap, and outputs power input through the power input unit 110 to the electronic product.

The current sensing unit 310 is connected to the power supply unit 110 through a latching relay 170 in which the contact is moved according to the drive of the switch 220 of the user to detect the flow of current. That is, when power is input through the power input unit 110, a current flows between the power input unit 110 and the power output unit 330. At this time, when the plug of the electronic product is connected to the power output unit 330 to drive the electronic product, a current of a predetermined level or more flows between the power input unit 110 and the power output unit 330. On the contrary, when the plug of the electronic product is connected to the power output unit 330 but the electronic product is not driven, a current of a predetermined level or less flows between the power input unit 110 and the power output unit 330. The current detector 310 detects a current below a predetermined level and outputs a control signal to the controller 320.

The controller 320 inputs a control signal generated when the current flowing in the multi tap from the current detector 310 is below a predetermined level, and controls the latching relay 170 in response thereto. That is, the latching relay 170 is controlled to move the contact of the latching relay 170 toward the switch 220.

1 is a block diagram illustrating a configuration of a standby power saving apparatus according to an embodiment of the present invention.

2 is a flowchart illustrating a standby power saving method according to an embodiment of the present invention.

3 is a block diagram illustrating a configuration of a standby power saving apparatus according to another embodiment of the present invention.

4 is a block diagram illustrating a configuration of a standby power saving apparatus according to another embodiment of the present invention.

<Explanation of symbols for the main parts of the drawings>

110: power input unit 120: control signal input unit

130: first control unit 140: second control unit

150: first power supply unit 160: second power supply unit

170: latching relay

Claims (12)

A power input unit to which power is input; First and second power supply units connected to the power input unit and configured to generate and supply first and second power sources, respectively; A control unit receiving a control signal according to a current state divided into a standby mode or a driving mode of the first and second power supply units; A latching relay configured to control a connection between the power input unit and the first and second power supply units by moving a contact according to an output signal of the controller; A control signal input unit connected to the control unit and inputting a control signal generated by an external remote controller to be transmitted to the control unit; And a switch connected to the controller to generate a control signal by an on / off operation.  The controller includes a first controller for inputting a control signal when the current state is a standby mode, and a second controller for inputting a control signal when the current state is a driving mode. The latching relay consumes current while the contact moves, and does not consume current while maintaining the contact. The method of claim 1, The first control unit moves the contact point of the latching relay to the second power supply unit so that the power input unit and the second power supply unit are connected, and the second control unit moves the contact point of the latching relay to the first power supply unit and the power input unit and the first power supply unit. The first power supply unit is connected, the power supply of the first power supply unit is supplied to the first control unit, the standby power saving device, characterized in that the power supply of the second power supply unit is supplied to the second control unit. delete delete delete delete delete delete delete delete delete delete

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