KR102272062B1 - Multi-Tap for Cutting Off Standby Power of Computer Peripherals - Google Patents

Abstract

The present invention is to provide a multi-tap that automatically cuts off power supply to computer peripheral devices (monitor, printer, speaker, etc.) in standby mode (power saving mode) while using a computer to cut off standby power of computer peripheral devices, according to the present invention. The characteristics of the multi-tap to cut off standby power for computer peripherals are a power cable that is electrically connected to the constant power from the outside to provide power to the multi-tap to cut off standby power, and a plug at the end of the power connection line provided for a plurality of computers and computer peripherals is inserted, respectively. A plurality of pair of connecting terminal units are respectively formed at positions corresponding to the plug insertion port and the plug insertion port, and the power applied through the power cable and the computer and peripheral devices of the computer are electrically connected through the plug inserted into the plug insertion port. and a power supply control unit for automatically shutting off or automatically supplying power to at least one sub-plug insertion port in response to the magnitude of the current detected from the computer plug inserted into the main plug insertion hole.

Description

Multi-Tap for Cutting Off Standby Power of Computer Peripherals

The present invention automatically cuts off power supply to computer peripherals (monitor, printer, speaker, etc.) in standby mode (power saving mode) while using the computer, and automatically supplies power to computer peripherals when the standby mode is released. It is about a power-off multi-tap

In general, various peripheral devices are connected to a computer. Among these computer peripheral devices, a device having a function of shutting off power by itself to save power is provided when the computer enters a power saving mode. For example, the monitor turns off the screen when the computer is in sleep mode to reduce standby power so that power consumption is about 15W. When the computer is turned off, the monitor stops functioning and enters the standby state. Power is typically wasted around 4W. Also, the printer always consumes about 4W of power.

As described above, in the prior art, when the computer enters the monitor power-off mode, the monitor screen is turned off to reduce power consumption in order to reduce unnecessary power wastage, thereby saving standby power. Power is supplied to peripheral devices such as speakers as it is, and standby power is wasted.

In addition, in the case of 'off' the power of the computer, standby power is wasted in the computer and peripheral devices, and thus unnecessary wasted power must be produced. At this time, there is a problem such as CO2 is generated, which becomes a factor of environmental pollution.

As a method to solve this problem, the invention of "Standby power interruption device for computers and computer peripherals" of Korean Patent No. 10-1446936 is a computer peripheral device in standby mode (power saving mode) or monitor power off mode while using a computer. When the power supply is completely cut off and the computer is turned off, the power of the computer and peripheral devices is completely cut off, thereby providing a device having a function of completely shutting off standby power.

However, in the case of such an existing standby power blocking device, a control unit for controlling to cut off the power supplied to the outlet power switching unit and the peripheral outlet is used as a microcomputer.

As such, the conventional standby power blocking device has a problem in that small breakdowns frequently occur due to the use of a microcomputer, and problems in A/S and costs are additionally generated. In particular, the microcomputer has a problem in that it is difficult for consumers to access it as additional costs are incurred due to its high price.

In the case of recent computers, the current may be as low as 90 mA or less when in power saving mode, but in the case of users using older computers, current of 90 mA or more may flow when the computer is in power saving mode. In this case, there are cases in which the power of the peripherals of the computer is not cut off due to the operation error of the microcomputer (misunderstood as turning on the computer) when the computer is in power saving mode, even if the existing micom uses a standby power cut-off multi-tap.

In other words, the standby power blocking multi-tap used by the existing microcontroller operates according to how the computer reads and stores the power consumption range and standby power range during initial setting, so the operation of the standby power range area after the computer is turned off is It operates correctly due to a large power difference compared to power consumption, but there is a difficulty in shutting off power to peripheral devices because comparison judgment in the power saving mode area may be ambiguous.

Therefore, there is a disadvantage in that all computer users cannot shut off peripheral devices when the computer is in power saving mode with the standby power blocking multi-tap applied with the existing micom.

Registered Patent Publication No. 10-1446936 (Registration Date 2014.09.26.) Registered Patent Publication No. 10-1072489 (Registration Date 2011.10.05.)

Therefore, the present invention has been devised to solve the above problems, and when the computer is in standby mode (power saving mode), the power supply of the computer peripheral devices (monitor, printer, speaker, etc.) is automatically cut off to provide the standby power of the computer peripheral device. The purpose is to provide a multi-tap that blocks

An object of the present invention is to provide a multi-tap for blocking standby power of a computer peripheral device that automatically supplies power to the computer peripheral device again when the computer is released from standby mode.

An object of the present invention is to provide a multi-tap that automatically cuts off standby power of computer peripherals using only passive elements such as transistors and relays without a microcomputer.

The present invention uses a variable resistor instead of a microcomputer and, when all computer users set the initial setting, adjust the variable resistor in the area where the peripheral device can be turned off in the computer power saving mode and set the variable resistor only once, and when any computer enters the power saving mode, the peripheral device automatically turns on. An object of the present invention is to provide a multi-tap capable of implementing a power-off situation.

Other objects of the present invention are not limited to the above-mentioned objects, and other objects not mentioned will be clearly understood by those skilled in the art from the following description.

A feature of the multi-tap for blocking standby power of a computer peripheral device according to the present invention for achieving the above object is a power cable that is electrically connected to a constant power from the outside to provide power to the multi-tap for blocking standby power, a plurality of computers and computers A plug insertion hole into which a plug at the end of a power connection line provided for each peripheral device is respectively inserted, and a pair of connection terminal portions are formed in a plurality at positions corresponding to the plug insertion hole, respectively, to be inserted into the plug insertion hole and the power applied through the power cable A copper piece for connection that is electrically connected to a computer and peripheral devices of the computer through a plug that automatically controls power supply to at least one sub-plug insertion port in response to the magnitude of the current detected by the computer plug inserted into the main plug insertion port and a power supply control unit for blocking or automatically supplying power, wherein the power supply control unit controls the supply of power to at least one sub-plug insertion hole when the magnitude of the current detected from the plug of the computer inserted into the main plug insertion hole is greater than a preset current value It is characterized in that the power of the computer peripheral device is automatically supplied again when the standby mode of the computer inserted into the main plug insertion hole is released.

In addition, the plug insertion hole includes one main plug insertion hole into which a computer plug is inserted, and at least one sub-plug insertion hole into which the plugs of the computer peripheral devices are respectively inserted.

In addition, the power supply control unit includes a sensor detection unit for detecting the magnitude of the current from the plug of the computer inserted into the main plug insertion hole, and a current value corresponding to the amplification gain adjusted by the variable resistor by inputting the signal detected by the sensor detection unit as an input An amplifying unit for outputting an operation signal for driving a relay, and switching the operation of at least one relay for supplying power to at least one or more sub-plug insertion holes by operating a transistor through an operation signal output from the amplifying unit Includes a relay drive.

In addition, the amplifying unit includes a first amplifying unit for outputting a first operation signal based on the magnitude of the current detected by the sensor detection unit, and receiving the first operation signal output from the first amplifying unit as an input to the value of the variable resistor. and a second amplifier for outputting a second operation signal with the total resistance adjusted by the .

In addition, the amplification unit receives a current detected by the sensor detection unit through a (+) terminal, a first amplifying unit connected to a resistor connected in parallel through a (-) terminal, and a first amplifying unit 421 through a (+) terminal A first operation signal output from the is input, and a resistor connected in parallel to a (-) terminal and a second amplifier to which a variable resistor is connected.

In addition, the relay driving unit is characterized in that it controls the operation of the relay through the operation signal output from the amplification unit input to the drain terminal of the FET connected to each relay.

In addition, the standby power cut-off multi-tap of the computer peripheral device further comprises a display unit for displaying whether power is connected to one side of the plug insertion port, respectively, and a switch unit for switching the connection of power to one side of the plug insertion port, respectively, The switch unit is characterized in that when the power connection of the switch unit for switching the power of the main plug insertion port is turned off, the sub plug insertion port is unconditionally switched off regardless of whether the corresponding switch unit is in the switch unit.

The standby power blocking multi-tap of the computer peripheral device according to the present invention as described above has the following effects.

First, it is possible to prevent wasted power consumption by automatically shutting off the power supply to the computer peripheral devices (monitor, printer, speaker, etc.) in standby mode (power saving mode) while using the computer, thereby blocking the standby power of the computer peripheral device.

Second, when the computer is released from the standby mode, the power of the computer peripheral device is automatically supplied again, and the inconvenience caused in the use of the computer peripheral device can be solved by blocking the standby power.

Third, it is possible to automatically cut off the standby power of computer peripherals using only passive elements such as transistors and relays without a microcomputer, so it is possible to prevent minor breakdowns caused by the use of microcomputers. can prevent

Fourth, it can be configured only with passive elements such as transistors and relays without an expensive microcomputer in the configuration of a multi-tap for blocking standby power of computer peripherals, so that low-cost products can be produced, making it easy for consumers to access.

1 is a configuration diagram showing the configuration of a standby power cut-off multi-tap of a computer peripheral device according to an embodiment of the present invention;
FIG. 2 is a block diagram showing the configuration of the power supply control unit of FIG. 1 in detail; FIG.
3 is a circuit diagram showing the configuration of the amplification unit of FIG. 2 in detail;
4 is a circuit diagram showing the configuration of the relay driving unit of FIG. 2 in detail;

Other objects, characteristics and advantages of the present invention will become apparent from a detailed description of the embodiments with reference to the accompanying drawings.

A preferred embodiment of the standby power blocking multi-tap of the computer peripheral device according to the present invention will be described with reference to the accompanying drawings. However, the present invention is not limited to the embodiments disclosed below, but can be implemented in various different forms, and only this embodiment allows the disclosure of the present invention to be complete and to fully convey the scope of the invention to those of ordinary skill in the art. It is provided to inform you. Therefore, the configuration shown in the embodiments and drawings described in the present specification is only one of the most preferred embodiments of the present invention and does not represent all the technical spirit of the present invention, so various equivalents that can replace them at the time of the present application It should be understood that there may be water and variations.

1 is a block diagram showing the configuration of a standby power cut-off multi-tap of a computer peripheral device according to an embodiment of the present invention.

As shown in Figure 1, the standby power cut-off multi-tap of the computer peripheral device of the present invention is a power cable 100, plug insertion holes 210, 220, 230, 240, copper for connection 300, power supply and a control unit 400 .

At this time, the power cable 100 is electrically connected to the constant power from the outside to provide power to the standby power cut-off multi-tap.

In the plug insertion hole, a plug at an end of a power connection line provided for each of a plurality of computers and computer peripheral devices is respectively inserted. In this case, the plug insertion hole includes one main plug insertion hole 210 and at least one sub-plug insertion hole 220 , 230 , 240 . The main plug insertion hole 210 may be inserted into a computer plug, and the sub plug insertion hole 220 , 230 , 240 may be inserted into the plug of a computer peripheral device, respectively. At this time, although three sub-plug insertion holes 220 , 230 , and 240 are illustrated, it is not limited thereto, and it should be noted that there may be fewer or more than three.

The copper piece 300 for connection has a plurality of pair of connection terminal parts 310 and 320 formed at positions corresponding to the plug insertion holes 210, 220, 230, and 240, respectively, to connect the power cable 100. Power applied through the plug is electrically connected to the computer and peripheral devices of the computer through the plugs inserted into the plug insertion holes 210, 220, 230, and 240.

The power supply control unit 400 automatically cuts off the power supply to at least one or more sub-plug insertion holes 220 , 230 , 240 in response to the magnitude of the current detected from the computer plug inserted into the main plug insertion hole 210 . or automatically supplied. At this time, the power supply control unit 400 cuts off or supplies power to all of the sub-plug insertion holes 220 , 230 , and 240 at the same time.

That is, when the magnitude of the current detected from the computer plug inserted into the main plug insertion hole 220 is less than a preset current value (about 90 mA), the power supply control unit 400 controls at least one sub-plug insertion hole 220 ( 230 and 240 automatically cut off the power supply. In this case, the power consumption of the computer is reduced as the computer is switched to the standby mode (power saving mode) while the computer is in use.

Accordingly, when the computer is in standby mode (power saving mode), the power supply to peripheral devices (monitor, printer, speaker, etc.) is automatically cut off, and the standby power of the computer peripheral device is cut off and power consumption is wasted as standby power of the computer peripheral device. can be prevented.

And when the magnitude of the current detected from the plug of the computer inserted into the main plug insertion hole 210 is greater than a preset current value (about 90 mA), the power supply control unit 400 is at least one sub-plug insertion hole 220, 230. (240) automatically supply the power supply.

In this case, as the standby mode of the computer is released, the power consumption of the computer increases again.

Accordingly, by automatically supplying power to the computer peripheral device again when the computer is released from the standby mode, it is possible to quickly recover the unusable use of the computer peripheral device due to the interruption of standby power.

FIG. 2 is a block diagram showing the configuration of the power supply control unit of FIG. 1 in detail.

As shown in FIG. 2 , the power supply control unit 400 includes a sensor detection unit 410 , an amplification unit 420 , and a relay driving unit 430 .

The sensor detection unit 410 detects the magnitude of the current in the plug of the computer inserted into the main plug insertion hole (210). At this time, when the computer is switched to the standby mode (power saving mode), the amount of current generally detected is lowered to about 90 mA or less.

The amplifying unit 420 outputs an operation signal for driving a relay at a current value corresponding to an amplification gain adjusted by a variable resistor by receiving the signal detected by the sensor detecting unit 410 as an input. At this time, the amplifying unit 420 includes a first amplifying unit 421 for outputting a first operation signal based on the magnitude of the current detected by the sensor detecting unit 410 , and a first amplifying unit output from the first amplifying unit 421 . and a second amplifying unit 422 that receives the first operation signal as an input and outputs a second operation signal with the total resistance adjusted by the value of the variable resistor.

At this time, the value of the current flowing through the second amplifying unit 422 is determined by adjusting the amplification gain of the second amplifying unit 422 by connecting a variable resistor in series to the second amplifying unit 422 . Accordingly, the second amplifying unit 422 is activated when a current equal to or greater than a predetermined current flows to output a second operation signal.

According to the present invention, the second amplifying unit 422 can automatically output the second operation signal according to the standby mode (power saving mode) of the computer by using the characteristics of the second amplifying unit 422 . That is, if the current value of the second amplifying unit 422 is preset to the amount of current detected when the computer is switched to the standby mode (power saving mode) (about 90 mA), the second amplifying unit 422 is the If it is switched to standby mode (power saving mode) and the flowing current value is less than the predetermined current value, the second operation signal is not output. Conversely, the standby mode (power saving mode) of the computer is released and the flowing current value exceeds the predetermined current value. Then, the second operation signal is output.

FIG. 3 is a circuit diagram showing the configuration of the amplifying unit of FIG. 2 in detail.

As shown in FIG. 3, the amplifying unit 420 includes a (+) terminal to which the current detected by the sensor detection unit 410 is input, and a (-) terminal to which a resistor connected in parallel is connected to the first amplifying unit ( 421) and a (+) terminal to which a first operation signal output from the first amplifier 421 is input, and a (-) terminal to a second amplifier to which a resistor and a variable resistor 423 connected in parallel are connected ( 422).

Through this configuration, when the value of the variable resistor 423 is determined and fixed, the total resistance value of the second amplifying unit 422 is determined, and the value of the current flowing through the second amplifying unit 422 is determined. At this time, the second amplifying unit 422 is activated when a current equal to or greater than the total resistance flows, and a second operation signal is output. In addition, the second amplifying unit 422 does not operate when a current less than the total resistance flows, so that the second operation signal is not output.

In addition, the relay driving unit 430 operates a transistor through an operation signal output from the amplifying unit 420 to supply power to at least one or more sub-plug insertion holes 220, 230, and 240. At least one or more relays switch the operation of

At this time, the relay driving unit 430 corresponds to all sub-plug insertion holes 220, 230, and 240 1:1 to configure the relay. And the relay driving unit 430 switches the operation of all the relays to cut off or supply power to all the sub-plug insertion holes 220 , 230 , and 240 at the same time.

4 is a circuit diagram illustrating in detail the configuration of the relay driving unit of FIG. 2 .

As shown in FIG. 3 , the relay driving unit 430 operates the relay 432 through the operation signal output from the amplifying unit 420 input to the drain terminal of the FET 431 connected to each relay 432 . control the operation of

That is, when the amplifier 420 outputs an operation signal to the FET 431 to which the relay is connected, the FET 431 is turned on to operate the relay. In addition, when the amplifier 420 does not output the operation signal to the FET 431 to which the relay 432 is connected, the FET 431 is turned off and the relay 432 is also turned off, so that all sub-plug insertion holes ( Power to 220 , 230 , and 240 is cut off.

And as shown in FIG. 1, the standby power cut-off multi-tap of the computer peripheral device includes a display unit 500 for indicating whether power is connected to one side of the plug insertion hole 200, respectively, and a plug insertion hole 200 at one side of each. It may further include a switch unit 600 for switching the connection of power.

At this time, the switch unit 600 is the switch unit 600 for switching the power of the main plug insertion hole 200, when the power connection is off, the sub-plug insertion hole 220, 230, 240 is the corresponding switch unit ( 600) may be unconditionally switched off regardless of whether or not there is.

Although the technical idea of the present invention described above has been specifically described in the preferred embodiment, it should be noted that the above-described embodiment is for the purpose of explanation and not for the limitation thereof. In addition, those of ordinary skill in the technical field of the present invention will understand that various embodiments are possible within the scope of the technical spirit of the present invention. Therefore, the true technical protection scope of the present invention should be determined by the technical spirit of the appended claims.

100: power cable 200: plug insertion hole
210: main plug insertion hole 220, 230, 240: sub plug insertion hole
300: copper for connection 310, 320: connection terminal part
400: power supply control unit 410: sensor detection unit
420: amplifying unit 421: first amplifying unit
422 ; Second amplification unit 423: variable resistor
430: relay driver 431: transistor (FET)
432: relay 500: display unit
600: switch unit

Claims (7)

A power cable that is electrically connected to the constant power from the outside and provides power to the standby power cut-off multi-tap;
A plug insertion hole including one main plug insertion hole into which a computer plug is inserted, and at least one sub-plug insertion hole into which plugs of computer peripheral devices are respectively inserted;
A pair of connecting terminal units are formed in a plurality of positions corresponding to the plug insertion hole, respectively, for connection to be electrically connected to the computer and peripheral devices of the computer through the power applied through the power cable and the plug inserted into the plug insertion port East side,
When the amount of current detected from the computer plug inserted into the main plug insertion hole is less than the preset current value of 90 mA in the standby mode with the computer power turned on while using the computer, at least one sub-plug insertion hole It automatically cuts off the power supply of the computer to completely cut off the standby power of the computer peripherals, and the current detected from the computer plug inserted into the main plug insertion port in the standby mode when the computer power is on while the computer is in use. When the size is greater than the preset current value of 90mA, the power supply control unit automatically supplies power to at least one sub-plug insertion hole and automatically supplies power to the computer peripheral device again when the computer inserted into the main plug insertion hole is released from the standby mode; ,
a display unit at one side of the plug insertion port to indicate whether power is connected, respectively;
and a switch unit for switching the connection of power to one side of the plug insertion hole, respectively,
The power supply control unit
a sensor detection unit for detecting the magnitude of the current in the plug of the computer inserted into the main plug insertion hole;
an amplifying unit for outputting an operation signal for driving a relay at a current value corresponding to an amplification gain adjusted with a variable resistor by inputting the signal detected by the sensor detecting unit;
and a relay driving unit for switching the operation of at least one relay for supplying power to at least one or more sub-plug insertion holes by operating a transistor through an operation signal output from the amplifying unit,
the amplification unit
a first amplifier for outputting a first operation signal based on the magnitude of the current detected by the sensor detection unit;
and a second amplifier for outputting a second operation signal with the total resistance adjusted by the value of the variable resistor as input to the first operation signal output from the first amplifier,
When the switch unit for switching the power of the main plug insertion port is turned off when the power connection of the switch unit is turned off, the sub plug insertion port is unconditionally switched off regardless of whether the switch unit is a standby power cutoff multi-tap of a computer peripheral. delete delete delete The method of claim 1,
the amplification unit
A first amplifier to which a current detected by the sensor detection unit is input to a (+) terminal and a resistor connected in parallel to a (-) terminal is connected;
A multi-tap for blocking standby power of a computer peripheral device comprising a (+) terminal to which a first operation signal output from the first amplifying unit is input, and a second amplifying unit to which a resistor and a variable resistor are connected in parallel to a (-) terminal. The method of claim 1,
The relay driving unit controls the operation of the relay through the operation signal output from the amplification unit input to the drain terminal of the FET connected to each relay. delete

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