KR20110092948A - The outlet of disconnecting standby power - Google Patents

Abstract

PURPOSE: An outlet for disconnection of standby power is provided to efficiently prevent the loss of standby power having a simple structure. CONSTITUTION: An outlet body(10) includes a plug groove(11) which is combined with a power plug of an electronic device. A standby power disconnecting module(20) includes a standby power disconnecting circuit. The standby power disconnecting module disconnects standby power. A front surface cover(40) is combined with the outlet body. A protective housing protects the outlet body and standby power disconnecting module.

Description

Flush Out Standby Power Receptacle {The Outlet of Disconnecting Standby Power}

The present invention relates to an embedded standby power cut-off outlet, and more particularly, has a simple and simple structure, and more effectively prevents standby power loss. Particularly, the standby power cut-off module is integrated into the plug groove of the outlet. As it relates to a buried type standby power cut-off outlet that can facilitate the convenience of use.

In homes and offices, a power strip or an outlet (hereinafter referred to as an outlet) is widely used to supply power to an electronic device.

On the other hand, even when the power switch of the electronic device is turned off, if the power plug of the electronic device is not disconnected from the outlet, the current applied to the socket of the outlet is transferred to the corresponding appliance through the plug of the electronic device. It is known to be applied at about 5W per hour.

Therefore, when using an electrical outlet, the power plug must be completely disconnected from the outlet when not in use, so that standby power loss can be reduced.

As such, even when the electronic device is off, standby power loss occurs when the electronic device is connected to the outlet. Therefore, to prevent the standby power loss, the power plug of the electronic device must be completely unplugged from the outlet.

However, it is very cumbersome to pull out the power plug every time you stop using the electronics. So, while you are aware of the standby power consumption in your home or office, keep the electronics and outlets connected. Only the power is off.

In order to solve this problem, an outlet for preventing standby power loss by cutting off standby power has been researched and developed in various places. However, the known ones are inadequate due to the complicated structure and the increased cost and failure rate. . In particular, since a structure in which a standby power blocking module for blocking standby power is embedded in a plug groove of an outlet has not been developed yet, research and development thereof is required.

An object of the present invention, while having a simple and simple structure can prevent the standby power loss more effectively, especially the buried type that can facilitate the use as the standby power blocking module is integrally installed to be embedded in the plug groove of the outlet It is to provide an outlet for blocking standby power.

The object is an outlet body having a plurality of plug grooves detachably coupled to the power plug of the electronic device; A standby power cut-off module having at least one region mounted in a first plug groove of the plurality of plug grooves, the standby power blocking circuit blocking the standby power; A front cover coupled to a front surface of the outlet body to form a front surface of the outlet body; And a protective housing disposed at the rear of the front cover with the outlet body and the standby power cutoff module interposed therebetween to protect the outlet body and the standby power cutoff module. Is achieved.

Here, the outlet body, the plurality of plug grooves are formed therein, the main body plate portion arranged in parallel with the installation wall surface; A boss portion extending from the rear surface of the body plate portion toward the protective housing and having a component accommodating space therein; And a power supply terminal module provided in one component accommodation space in the boss at a position corresponding to the second plug groove among the plurality of plug grooves.

It may further include a module support member coupled to the rear of the outlet body to partially support the standby power blocking module.

The standby power blocking module may include a module cover embedded in the first plug groove; A printed circuit board inserted into the other part accommodating space in the boss and including the standby power cutoff circuit; And a module body coupled to the module support member and partially inserted into the other component accommodation space in the boss portion with the printed circuit board interposed therebetween.

The apparatus may further include a holder disposed to partially surround the protective housing to support the protective housing.

In order to assemble the position of the holder with respect to the protective housing, the protective housing may be further formed with a seat groove in which the holder is disposed.

The holder, the rear arrangement portion disposed on the rear side of the seat groove of the protective housing; A bent portion that is bent at the rear disposition portion and disposed at a side of the seat groove; And a coupling part which is bent again at the bending part and a hole is formed in the plate surface.

According to the present invention, the standby power loss can be prevented more effectively while having a simple and simple structure, and in particular, since the standby power blocking module is integrally installed to be embedded in the plug groove of the outlet, the convenience of use can be achieved. have.

1 is a perspective view of an embedded standby power cut-off outlet according to an embodiment of the present invention;
Fig. 2 is a front view of Fig. 1,
3 is a side view of FIG. 1;
4 and 5 are exploded perspective views of FIG. 1 respectively shown at different angles;
6 is a flowchart of a standby power cut-off circuit,
7 is a control block diagram of an embedded standby power cut-off outlet according to another embodiment of the present invention;
8 and 9 are various embodiments of the embedded standby power cut-off outlet of the present invention, respectively.

Hereinafter, with reference to the accompanying drawings will be described a preferred embodiment of the present invention.

1 is a perspective view of an embedded standby power cut-off outlet according to an embodiment of the present invention, FIG. 2 is a front view of FIG. 1, FIG. 3 is a side view of FIG. 1, and FIGS. 4 and 5 are respectively shown from different angles. 1 is an exploded perspective view and FIG. 6 is a flowchart of a standby power interruption circuit.

As shown in these figures, the embedded standby power cut-off outlet of this embodiment discloses a two-spherical type as an embodiment, one for power supply and the other for standby power cut off. Of course, the scope of the present invention need not be limited thereto.

The buried standby power cut-off outlet of this embodiment includes a socket body 10, the standby power cut-off module 20, the module support member 30, the front cover 40, and the protective housing 50. More about each configuration.

The outlet body 10 is provided with a plurality of plug grooves 11 detachably coupled to the power plug of the electronic device (not shown).

Since the embedded standby power cut-off outlet of this embodiment is a two-hole type, a total of two plug grooves 11 are formed, but one is used for blocking standby power. ) Is one, which will be referred to as the second plug groove. Of course, the number thereof may not limit the scope of the present invention.

The outlet body 10, the above-described plug groove 11 is formed therein and extends toward the protective housing 50 from the main body plate portion 12 and the rear surface of the main body plate portion 12 is disposed parallel to the installation wall surface A power supply terminal module provided in the boss part 13 having the component accommodating space 13a formed therein and the one part accommodating space 13a in the boss part 13 at a position corresponding to the second plug groove 11. (14) is provided.

The power supply terminal module 14 is formed with an insertion terminal portion 14a into which a power plug of an electronic device is inserted, and the insertion terminal portion 14a is disposed to correspond to the through hole 30a of the module support member 30. For reference, since the power supply terminal module 14 is a component provided in a conventional outlet, detailed description thereof will be omitted.

The standby power blocking module 20 is mounted to be embedded in a first plug groove (not shown).

The standby power blocking module 20 includes a module cover 21 embedded in the first plug groove, and a standby power blocking circuit inserted into the other part accommodating space 13a in the boss 13 to block standby power. The module body 23 coupled to the printed circuit board 22 and the module support member 30 and partially inserted into the other component receiving space 13a in the boss portion 13 with the printed circuit board 22 therebetween. ).

While having a simple and simple structure as described above, it is possible to more effectively prevent standby power loss, and in particular, as the standby power blocking module 20 is integrally installed to be embedded in a plug groove of an outlet, convenience of use can be achieved. As for the standby power cutoff circuit, reference is made to a known one.

Module support member 30 is coupled to the rear of the outlet body 10 serves to partially support the standby power blocking module 20. It may be provided in a thin plate-like body. Of course, in some cases, the module support member 30 may be integrated with the standby power blocking module 20.

The front cover 40 is coupled to the front of the outlet body 10 to form the front of the outlet body (10). Since the outlet body 10 is a two-spherical shape, two holes 40a are formed through the front cover 40. On the back of the front cover 40, a plurality of assembly ribs 40b are formed for each position.

The protective housing 50 is disposed at the rear of the front cover 40 with the outlet body 10 and the standby power blocking module 20 interposed therebetween to protect the outlet body 10 and the standby power blocking module 20. Do it.

Inside the protective housing 50, the upper region 50a in which the standby power cut-off module 20 is disposed is empty, and the lower region 50b is a rear part of the power supply terminal module 14 or the module support member 30. It forms an assembly structure for assembling with the field (30b). A bolt hole 50c is formed at the inner edge of the protective housing 50.

The holder 60 is further used to prevent any deviation of this protective housing 50. The holder 60 may be an elastic bracket, and serves to support the protective housing 50 in a state in which the holder 60 is partially enclosed.

In order to assemble the position of the holder 60 with respect to the protective housing 50, the protective housing 50 is further provided with a seat groove 50d in which the holder 60 is disposed.

The holder 60 is bent at the rear surface arrangement portion 60a disposed on the rear side of the seat groove 50d of the protective housing 50 and the rear surface arrangement portion 60a and disposed on the side surface of the seat groove 50d. The bent part 60b and the engaging part 60c which are bent again by the bent part 60b, and the through hole 60d is formed in a board surface are provided. In the present embodiment, the rear arrangement part 60a is provided in a non-linear shape, but this is only one embodiment.

According to the buried standby power cut-off outlet of this embodiment having such a configuration, it is possible to prevent the standby power loss more effectively while having a simple and simple structure, in particular, the standby power cut-off module 20 is integrally embedded in the plug groove of the outlet As it is installed as it is possible to facilitate the convenience of use.

Meanwhile, the standby power blocking circuit will be described with reference to FIG. 6 as follows.

First, it is determined whether or not the overload in the state that the power supply (S11) is in progress (S12). As a result of the determination, if it is not an overload, it is determined whether the load is a predetermined capacity, for example, 25 w or more (S13). If the load is more than 25w, it is determined again whether the measured value is greater than or equal to the initial value (S14), and if the condition is met, the control is turned off after a predetermined time, for example, two minutes (S15). However, if the measured value is less than the initial value, it feeds back to the power supply and current detection step (S18). Next, if the load is not a predetermined capacity, for example, 25w or more in the determination step of S13 (S16), the initial standby power is stored (S16), and then it is determined whether the home appliance is operated (S17). As a result of the determination, if there is no operation of the home appliance, the process proceeds to step S15, and if there is an operation of the home appliance, the power supply and current are sensed (S18), and the process proceeds to step S14.

Of course, since the standby power cut-off circuit is only one embodiment, the scope of the present invention is not necessarily limited to the matters shown in the drawings.

7 is a control block diagram of an embedded standby power cut-off outlet according to another embodiment of the present invention.

AC220V (1) power for supplying power to the wall outlet of the home goes through the power supply section (3) rectifying AC power to supply a stable power to the microcomputer (5) of the printed circuit board.

First, when an overload or overvoltage comes in, the circuit protection unit 2 detects the power supply to the outlet 14 to prevent human injury or disaster in advance.

When using a home appliance such as a VCR or a TV connected to the outlet 14 and supplying power to the outlet by controlling the relay unit 4 with a switch 9 or a remote controller, the initial standby power value of the product plugged into the outlet is current. The sensor 6 sends the data to the MICOM 5 and the microcomputer 5 stores the memory.

After remembering the initial standby power value, if any product is used, the current sensing unit 6 detects the relay unit 4 and turns on the power supply 220V to the outlet 14. Even when no product is used, the current sensing unit 6 detects and sends the signal to the MICOM 5, which is judged by the MICOM 5 to control the relay unit 4, and after 2 minutes, the power supply to the outlet 14 220V To block.

The current sensing unit 6 includes a current sensor CT, a diode, a smoothing capacitor, a zener diode, and a resistor, and the current transformer CT is proportional to the power supplied to the home appliances connected to the outlet 14. A diode and a smoothing capacitor rectify and convert currents of the detected loads into a direct current signal so that the currents of the loads detected through the resistance are converted into voltages to enter the AD converter of the MICOM 5. do. The voltage input to the AD converter protects MICOM (5) through a zener diode so that it does not exceed 5V. When the load is not used, it is determined that the standby power because the voltage is low, and when the load is used, the power is supplied to and disconnected from the outlet 14 by determining the load power because the voltage is high.

The RF receiver 7 controls the relay unit 4 with an RF-only remote controller to supply or cut off power to the outlet 14.

The IR receiver 8 controls the relay unit 4 by using a remote control of a general household appliance to supply or cut off power to the outlet 14.

The switch 9 controls the relay unit 4 every time the switch is pressed to serve to cut off or supply power to the outlet 14.

The mode selector 10 serves to determine whether to use the RF mode or the IR mode.

The display unit 11 serves to display the product so as to visually recognize whether the product is in use or in a standby power state, and may be displayed by LEDs and LCDs.

The buzzer 12 serves to easily display the use of the product by sound.

The communication unit 13 is capable of interlocking with the wall pad using RS-232 or 485 communication, thereby controlling the relay unit 4 from the wall pad to cut off power to the outlet 14 to completely block standby power. Play a role.

8 and 9 are various embodiments of the embedded standby power cut-off outlet of the present invention, respectively.

In the above-described embodiments, the front surface of the standby power blocking module 20 has a circular shape, but as shown in FIGS. 8 and 9, the front surface of the standby power blocking module 20a may have a square shape.

8 and 9 illustrate a one- or three-pronged outlet having a square front standby power cut-off module 20a, respectively, but the structure and function of the present invention are the same as those of the above-described embodiments.

As described above, the present invention is not limited to the described embodiments, and various modifications and changes can be made without departing from the spirit and scope of the present invention, which will be apparent to those skilled in the art. Therefore, such modifications or variations will have to be belong to the claims of the present invention.

10: outlet body 11: plug groove
20: standby power cut off module 21: module cover
22: printed circuit board 23: module body
30 module support member 40 front cover
50: protective housing 60: holder

Claims (6)

An outlet body having a plurality of plug grooves to which a power plug of an electronic device is detachably coupled;
A standby power cut-off module having at least one region mounted in a first plug groove of the plurality of plug grooves, the standby power blocking circuit blocking the standby power;
A front cover coupled to a front surface of the outlet body to form a front surface of the outlet body; And
And a protective housing disposed at the rear of the front cover with the outlet body and the standby power blocking module interposed therebetween to protect the outlet body and the standby power blocking module. The method of claim 1,
The outlet body,
A plurality of plug grooves formed therein, the body plate portion being disposed in parallel with an installation wall surface;
A boss portion extending from the rear surface of the body plate portion toward the protective housing and having a component accommodating space therein; And
And a power supply terminal module provided in one component receiving space in the boss at a position corresponding to the second plug groove among the plurality of plug grooves. The method of claim 2,
The outlet for embedded embedded standby power is further coupled to the rear of the outlet body further comprises a module support member for supporting the standby power blocking module. The method of claim 3,
The standby power blocking module,
A module cover embedded in the first plug groove;
A printed circuit board inserted into the other part accommodating space in the boss and including the standby power cutoff circuit; And
And a module body coupled to the module support member, the module body being partially inserted into the other component receiving space in the boss portion with the printed circuit board interposed therebetween. The method of claim 1,
And a holder for partially enclosing the protective housing to support the protective housing. The method of claim 5,
A seating groove in which the holder is disposed is further formed in the protective housing to assemble the position of the holder with respect to the protective housing;
The holder has a rear arrangement portion disposed on the rear side of the rear seat groove of the protective housing, a bent portion bent from the rear arrangement portion and disposed on the side of the seat groove, and bent again at the bent portion and a hole in the plate surface. The embedded standby power cut-off outlet comprising a coupling part formed.

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