KR101098030B1 - Device for controlling electric power source - Google Patents

Abstract

The power control device according to the present invention is a device for controlling the power of a plurality of electronic devices, the central switching unit for temporarily shutting off all power connected to the plurality of electronic devices by being temporarily cut off and conducting, and the plurality of Each of the power supply connected to the electronic device of the control unit, and when the central switching unit is disconnected and is connected to a separate switching unit for cutting off the power connected to the plurality of electronic devices.

Switch, Network, Power Saving, Temporary Shutdown, Bulk Shutdown

Description

Power Control Unit {DEVICE FOR CONTROLLING ELECTRIC POWER SOURCE}

The present invention relates to a power supply control device.

Various technologies have been developed to build a network system among various electronic devices such as homes or companies and control them. Such a network system may collectively cut off power applied to the entire electronic device in order to save energy. In order to use some of the electronic devices in the collective blocking state, the collective blocking state must be released. In this case, power control is inconvenient, and when the batch cutoff state is released and the batch cutoff is not performed, it is difficult to achieve the effect of power saving.

Therefore, a switch is required to turn off the power of the entire electronic device and to use some electronic devices, and to keep the power cut off regardless of the previous state. Such a switch may use a network switch implemented by electronic control through a control circuit. However, these network switches are expensive and require standby power, resulting in the consumption of unnecessary power.

The technical problem to be achieved by the present invention is to efficiently control the power off of the network system at low cost without consuming standby power.

The power control device according to an embodiment of the present invention is a device for controlling the power of a plurality of electronic devices, and is temporarily cut off and then turned on, so that the central switching unit temporarily cuts off all power connected to the plurality of electronic devices. And an individual switching unit which controls power supplies connected to the plurality of electronic devices, and cuts off power connected to the plurality of electronic devices when the central switching unit is disconnected and is turned on.

When the individual switching unit is in a conductive state before the central switching unit is shut off, the individual switching unit is shut off after the central switching unit is shut off and conducting, and when the individual switching unit is in the blocking state before the central switching unit is shut off. The individual switching unit may maintain the blocking state after the central switching unit is disconnected and then turned on.

After the central switching unit cuts off all power connected to the plurality of electronic devices, the individual switching unit may be turned on when it is necessary to use some of the electronic devices.

The individual switching unit may be cut off after the use of the electronic device is terminated.

The individual switching unit may be connected between the central switching unit and the plurality of devices.

The individual switching unit may include a first switch connected between a power input end and a load end, a relay connected between the power input end and the load end, and connected in parallel with the first switch, and the first switch. It may include a second switch connected between the relay.

The relay may include a third switch facing each other and an electromagnet in which a coil connected to the second switch is wound.

The first switch may be in a blocked state when no physical force is applied, and the second switch may be in a conductive state when no physical force is applied.

When the current flows through the coil, the electromagnet generates a magnetic force, and the third switch may maintain a blocked state when the magnetic force is not generated.

When the first switch is changed from the disconnected state to the conduction state, the third switch is changed from the disconnected state to the conduction state, and the second switch is changed from the conduction state to the disconnected state or the power drawn into the power inlet end is When disconnected, the third switch may change from a conducting state to a blocking state.

The individual switching unit may include a first switch connected between a power input end and a load end, a relay connected between the power input end and the load end, and a relay connected in parallel with the first switch and the relay. A second switch, a third switch connected in parallel with the first switch, a third switch connected between the power inlet end and the load end, and connected in parallel with the first switch, and the load end and the It may include a fourth switch connected between the second switch.

The relay may include a fifth switch facing each other and an electromagnet in which a coil connected to the second switch is wound.

The first and third switches may be in a blocked state when no physical force is applied, and the second and fourth switches may be in a conductive state when no physical force is applied.

When the current flows through the coil, the electromagnet generates a magnetic force, and the fifth switch may maintain a blocked state when the magnetic force is not generated.

When the first switch is changed from the disconnected state to the conduction state, the fifth switch is changed from the disconnected state to the conduction state, and when the second switch is changed from the conduction state to the interruption state, the fifth switch is disconnected from the conduction state. Can change state.

When the third switch is changed from the shut-off state to the conduction state, the fifth switch is changed from the shut-off state to the conduction state, and the fourth switch is changed from the conduction state to the disconnection state or the power drawn into the power inlet end is When disconnected, the fifth switch may change from a conducting state to a blocking state.

The individual switching unit may include a switch including an electromagnet in which coils are wound, symmetrically interlocked with respect to a fixed shaft, one end selectively contacting a power inlet end, and the other end selectively contacting the coil, and the fixed axis. It may include an elastic member connected to the other end side of the switch.

When a physical force is applied to the other end of the switch, the elastic member may provide a resilient elastic force to the switch, and provide a restoring elastic force to the switch when the physical force is removed.

When a physical force is applied to the other end of the switch, the other end of the switch contacts the coil and the end of the switch contacts the power lead wire, a magnetic force is generated in the electromagnet, and the other end of the switch and the coil are caused by the magnetic force. When the contact of the switch is maintained, when a physical force is applied to one end of the switch, the contact of the other end of the switch and the coil is released, the contact of the end of the switch and the power lead can be released to remove the magnetic force.

The individual switching unit may include an electromagnet in which a coil is wound, a first switch selectively contacting the coil, a first elastic member connected to the first switch, and a second switch connected between a power inlet end and the first switch. And a second elastic member connected to the second switch.

The first elastic member may provide a restoring elastic force to the first switch to maintain the first switch in a blocked state when no physical force is applied to the first switch.

The second elastic member may provide a restoring elastic force to the second switch to maintain the conductive state when no physical force is applied.

When a physical force is applied to the first switch, the first switch is turned on, a magnetic force is generated in the electromagnet to maintain the conduction state of the first switch, and when a physical force is applied to the second switch, The second switch may be cut off to remove the magnetic force and the first switch may be cut off.

According to another embodiment of the present invention, a power control device includes a first switch connected between a power input end and a load end, and a relay connected between the power input end and the load end and connected in parallel with the first switch. And a second switch connected between the first switch and the relay, wherein the first switch remains blocked when no physical force is applied, and the second switch is applied by physical force. If it is not, it can maintain the conduction state.

The relay includes a third switch facing each other and an electromagnet in which a coil connected to the second switch is wound, and when the current flows through the coil, the electromagnet generates a magnetic force, and the third switch generates the magnetic force. If not, you can remain blocked.

According to another embodiment of the present invention, a power control device includes a first switch connected between a power input end and a load end, and a relay connected between the power input end and the load end and connected in parallel with the first switch. A second switch connected to the relay, a third switch connected in parallel with the first switch, a third switch connected between the power input terminal and the load terminal, and connected in parallel with the first switch A switch, and a fourth switch connected between the load end and the second switch, wherein the first and third switches remain blocked when no physical force is applied; 4 The switch can remain energized when no physical force is applied.

The relay includes a fifth switch facing each other and an electromagnet in which a coil connected to the second switch is wound, and when the current flows through the coil, the electromagnet generates a magnetic force, and the fifth switch generates the magnetic force. If not, you can remain blocked.

Power control apparatus according to another embodiment of the present invention is a switch comprising a coil, the electromagnet is wound around, symmetrically interlocking with respect to the fixed shaft, one end selectively contacting the power inlet end and the other end selectively contacting the coil, And connected to the other end of the switch with respect to the fixed shaft, and when a physical force is applied to the other end of the switch, the elastic member provides a resilient elastic force to the switch, and when the physical force is removed, And an elastic member for providing a restoring elastic force to the switch.

The power control apparatus according to another embodiment of the present invention is connected to an electromagnet in which a coil is wound, a first switch selectively contacting the coil, and the first switch, and providing a restoring elastic force to the first switch. A first elastic member, a second switch connected between a power inlet end and the first switch, and the second switch to keep the first switch shut off when no physical force is applied to the first switch; And a second elastic member connected to the second switch to provide a restoring elastic force to maintain the conductive state when no physical force is applied.

According to the present invention, it is possible to efficiently control the power off of the network system at low cost without consuming standby power.

DETAILED DESCRIPTION Hereinafter, exemplary embodiments of the present invention will be described in detail with reference to the accompanying drawings so that those skilled in the art may easily implement the present invention. The present invention may, however, be embodied in many different forms and should not be construed as limited to the embodiments set forth herein. In the drawings, parts irrelevant to the description are omitted in order to clearly describe the present invention, and like reference numerals designate like parts throughout the specification.

Throughout the specification, when a part is said to "include" a certain component, it means that it can further include other components, without excluding other components unless specifically stated otherwise. In addition, the terms “… unit”, “… unit”, “module”, etc. described in the specification mean a unit that processes at least one function or operation, which may be implemented by hardware or software or a combination of hardware and software. have.

A power control device according to an embodiment of the present invention will now be described in detail with reference to the drawings.

1 is a block diagram of a network system according to an embodiment of the present invention.

1, the network system 100 according to an embodiment of the present invention includes a switchboard 111, a network operation unit 112, a temperature control unit 113, a network control unit 114, a network switch 115, Device 116, power control device 200 and device 117.

The switchboard 111 receives power directly from the power line to supply power to the network switch 115 and the power control device 200.

The network manipulator 112 is a terminal for controlling the network system 100, and may be a conventional wall pad.

The temperature control device 113 is a device for controlling the room temperature of a home or a company where the network system 100 is installed, and the temperature is controlled through the network operation unit 112.

The network control unit 114 is a control circuit that controls the network switch 115 according to a user's instruction through the network operation unit 112.

The network switch 115 changes the power switching state of the device 116 connected to the network switch 115 according to the electronic control of the network controller 114.

The device 116 is typically an electronic device using electricity, and may include a plurality of lights, a computer, and the like, and the device 116 is powered or cut under the control of the network switch 115.

Device 117 is also a device that typically uses electricity, such as device 116, and may include a plurality of lights, computers, and the like. Unlike the device 116 under the control of the network switch 115, the device 117 is powered or cut off according to the control of the power control device 200.

Unlike the network switch 115 controlled through the network controller 114, the power control device 200 adjusts the power opening / closing state of the device 117 by a user's mechanical manipulation. The central switching unit 300 And individual switching unit 400.

The central switching unit 300 controls the opening and closing of the power supply of the device 117 by selectively transferring power applied from the switchboard 111 to the device 117 through the individual switching unit 400. When the central switching unit 300 is blocked by external manipulation or physical force, the blocking state is temporarily maintained and then automatically turned on. Meanwhile, the central switching unit 300 may be connected to the network operation unit 112 and operated by the network operation unit 112. Alternatively, the central switching unit 300 may be operated independently of the network operation unit 112.

The individual switching unit 400 is connected to each device 117 to control the power opening and closing state of each device 117, respectively. The individual switching unit 400 may be disconnected when the central switching unit 300 is shut off and is turned on, regardless of whether the individual switching unit 400 is in the conducting state or the blocking state before the central switching unit 300 is shut off. Keep it.

Referring now to Figure 2 will be described in detail the operation of the individual switching unit according to an embodiment of the present invention.

2 is a flowchart illustrating an operation of an individual switching unit according to an exemplary embodiment of the present invention.

Referring to FIG. 2, first, a user sets the network system 100 to a power saving mode (S210). Here, the power saving mode is a mode for saving power consumed when operating the network system 100 and may be applied at bedtime or when going out.

Subsequently, the power of the apparatus 117 is cut off by temporarily shutting off the central switching unit 300 (S220). In this case, as described above, the temporary blocking (S220) means that the central switching unit 300 is temporarily cut off and maintains a conductive state immediately.

After temporarily blocking the central switching unit 300 (S220), the individual switching unit 400 maintains the blocking state (S230). Subsequently, after determining whether the user needs to use some of the apparatuses 117 (S240), if necessary, the individual switching unit 400 is manually conducted (S250). If it is determined that it is not necessary to use some devices 117, the individual switching unit maintains the blocked state (S230).

After manually conducting the individual switching unit 400 (S250), the individual switching unit 400 maintains the conduction state (S260).

Then, it is determined whether the use of the device 117 is terminated (S270), and when the use is terminated, the individual switching unit 400 is manually blocked (S280). If it is determined that the use is not finished, the individual switching unit is kept in the conductive state (S260).

After the individual switching unit 400 is manually blocked (S280), the individual switching unit maintains a blocking state (S230).

Referring now to Figures 3 and 4 will be described in detail for the individual switching unit according to an embodiment of the present invention.

3 is a circuit diagram illustrating an individual switching unit according to an exemplary embodiment of the present invention, and FIG. 4 is a state diagram illustrating an opening and closing state of the individual switching unit illustrated in FIG. 3.

Referring to FIG. 3, an individual switching unit 410 according to an embodiment of the present invention is connected between a power input terminal Pi and a load terminal Lo. The power input terminal Pi is connected to the switchboard 111 through the central switching unit 300, and the load terminal Lo is connected to the device 117.

Individual switches 410 include switches 411 and 412 and relays 413.

The switch 411 is normally off when the external physical force is not applied and the state is shut off and the conductive state is maintained only when the physical force is applied. One end of the switch 411 is connected to the power input terminal Pi and the relay 413, and the other end of the switch 411 is connected to the load terminal Lo, the switch 412, and the relay 413.

The switch 412 is normally on when the external physical force is not applied, and the switch 412 is kept in a closed state only when the physical force is applied. One end of the switch 412 is connected to the switch 411 and the relay 413, and the other end of the switch 412 is connected to the relay 413.

The relay 413 includes a switch 414 and an electromagnet 415 facing each other. One end of the switch 414 is connected to the power input terminal Pi and the switch 411, and the other end of the switch 414 is connected to the switches 411 and 412. Electromagnet 415 is connected to the switch 412, the coil connected to the switch 412 is wound.

The relay 413 opens and closes the switch 414 by the magnetic force generated by the current flowing through the coil wound around the electromagnet 415.

On the other hand, the switch 414 is a normally off type that maintains a blocked state when no magnetic force is generated from the electromagnet 415 and maintains a conductive state when magnetic force is generated from the electromagnet 415.

The operation of the individual switching unit 410 shown in FIG. 3 will now be described in detail with reference to FIG. 4.

Referring to FIG. 4, open / close states Sa, Sb, and Sc of the switches 411, 412, and 414 are shown as a conduction state (on) and a cutoff state (off).

First, in the first section T1, the switch 411 maintains the blocked state, the switch 412 maintains the conducting state, and the switch 414 maintains the blocked state.

After that, when the switch 411 is turned on by the external physical force in the second section T2, and the switch 412 remains turned on, current flows through the coil wound around the electromagnet 415, thereby generating magnetic force. The switch 414 is conductive. As described above, since the switch 411 maintains the conduction state only at the moment when an external physical force is applied, the second section T2 is a relatively short time.

Subsequently, in the third section T3, the external physical force applied to the switch 411 is removed and the switch 411 is blocked. At this time, the switches 412 and 414 remain in a conductive state. Then, in the third section T3, the power input terminal Pi and the load terminal Lo are electrically connected to each other so that the individual switching unit 410 is turned on and maintains its state.

Then, the switch 412 is cut off by an external physical force in the fourth section T4, and thus the magnetic force generated from the electromagnet 415 is removed by cutting off the current provided to the coil wound on the electromagnet 415. , Switch 414 is blocked. Since the switch 412 remains in the conductive state only at the moment when the external physical force is applied, the fourth section T4 is a relatively short time. As a result, the switch 414 is blocked.

Subsequently, as the external physical force is removed in the fifth section T5, the switch 412 is turned on and the switch 414 remains blocked. That is, in the fifth section T5, the power input terminal Pi and the load terminal Lo are electrically disconnected from each other, so that the individual switching unit 410 is cut off and maintains the state.

In this case, although not shown in FIG. 4, instead of blocking the switch 412 in the fourth section T4, the power supply line Pi is cut off to cut off the current provided to the coil wound around the electromagnet 415, and the individual switching unit ( 410 may be blocked.

This disconnection state of the individual switching unit 410 is maintained until power is applied again, even if power is again supplied, that is, even if the central switching unit 300 changes from the disconnection state to the conduction state. Therefore, power is not supplied from the power input terminal Pi to the load terminal Lo.

Network switches used in the past consume power even during standby. On the contrary, the individual switching unit 410 according to the present invention needs only electric power to generate a current flowing through the coil in order to generate magnetic force in the electromagnet 415 only when the switch is used. Very little compared to the power used. Therefore, if the individual switching device 410 is applied to a device having a long standby time compared to the power usage time, the power can be controlled with less power.

Referring now to Figures 5 and 6 will be described in detail for the individual switching unit according to another embodiment of the present invention.

5 is a circuit diagram illustrating an individual switching unit according to another exemplary embodiment of the present invention, and FIG. 6 is a state diagram illustrating an open / closed state of the individual switching unit illustrated in FIG. 5.

Referring to FIG. 5, the individual switching unit 420 according to another embodiment of the present invention is also connected between the power input terminal Pi and the load terminal Lo.

Individual switch 420 includes switches 421, 422, 426, 427 and relay 423.

The switch 421 is a normally off type that maintains a blocked state when no external physical force is applied and maintains a conductive state only when a physical force is applied. One end of the switch 421 is connected to the power input terminal Pi and the relay 423, and the other end of the switch 421 is connected to the load terminal Lo and the switches 426 and 427.

The switch 422 is a normally on type that maintains the conduction state when no external physical force is applied and keeps the block state only when a physical force is applied. One end of the switch 422 is connected to the relay 413, and the other end of the switch 422 is connected to the switch 427.

The relay 413 includes a switch 424 and an electromagnet 425 facing each other. One end of the switch 424 is connected to the power input terminal Pi and the switch 421, and the other end of the switch 424 is connected to the switches 421, 426, 427 and the load terminal Lo. The electromagnet 415 is connected to the switch 422 and the coil is wound up.

The relay 423 opens and closes the switch 424 by the magnetic force generated by the current flowing through the coil wound around the electromagnet 425.

On the other hand, the switch 424 is a normally off type that maintains a blocked state when no magnetic force is generated from the electromagnet 425 and maintains a conducting state when magnetic force is generated from the electromagnet 425.

The switch 426 is a normally off type that remains blocked when no external physical force is applied and maintains the conduction state only when physical force is applied. One end of the switch 426 is connected to the power input terminal Pi and the switches 421 and 424, and the other end of the switch 426 is connected to the switches 421, 424 and 427 and the load terminal Lo. .

The switch 427 is a normally on type that maintains the conduction state when no external physical force is applied and keeps the block state only when a physical force is applied. One end of the switch 427 is connected to the switches 421, 424, 426 and the load terminal Lo, and the other end of the switch 427 is connected to the switch 422.

The operation of the individual switching unit 420 shown in FIG. 5 will now be described in detail with reference to FIG. 6.

Referring to FIG. 5, open / close states Sa, Sb, Sc, Sd, and Se of each of the switches 421, 422, 424, 426, and 427 are illustrated as a conduction state and an off state.

First, in the sixth section T6, the switch 421 maintains the blocked state, the switch 422 maintains the conducting state, and the switch 424 maintains the blocked state.

After that, when the switch 421 is turned on by an external physical force in the seventh section T7, and the switch 422 is kept turned on, current flows through a coil wound around the electromagnet 425 to generate magnetic force. The switch 424 is conductive. As described above, since the switch 421 remains in the conducting state only at the moment when an external physical force is applied, the seventh section T7 is a relatively short time.

Subsequently, in the eighth section T8, the external physical force applied to the switch 421 is removed and the switch 421 is cut off. At this time, the switches 422 and 424 remain in a conductive state. Then, in the eighth section T8, the power input terminal Pi and the load terminal Lo are electrically connected to each other so that the individual switching unit 420 is turned on and maintains its state.

Then, in the ninth section T9, the switch 422 is blocked by an external physical force, and thus the magnetic force generated from the electromagnet 425 is removed by cutting off the current provided to the coil wound on the electromagnet 425. . Accordingly, the switch 424 is blocked, and the switch 421 remains blocked.

Subsequently, as the external physical force is removed in the tenth section T10, the switch 422 is turned on and the switches 421 and 424 remain blocked. That is, in the tenth period T10, the power input terminal Pi and the load terminal Lo are electrically disconnected from each other, so that the individual switching unit 420 is cut off and maintains the state.

On the other hand, while the switch 426 maintains the blocking state for the sixth to tenth sections T6 ?? T10, the switch 426 is turned on by an external physical force in the eleventh section T11, and the switch ( When the state 427 remains in the conduction state, current flows through the coil wound around the electromagnet 425 so that the magnetic force is generated, so that the switch 424 is conducting. As described above, since the switch 426 maintains the conduction state only at the moment when an external physical force is applied, the eleventh section T11 is a relatively short time.

Subsequently, in the twelfth section T12, the external physical force applied to the switch 426 is removed and the switch 426 is blocked. At this time, the switches 427 and 424 remain in the conducting state. Then, in the twelfth section T12, the power input terminal Pi and the load terminal Lo are electrically connected to each other so that the individual switching unit 420 is turned on and maintains its state.

Then, in the thirteenth section T13, the switch 427 is cut off by an external physical force, and thus the magnetic force generated from the electromagnet 425 is removed by cutting off the current provided to the coil wound on the electromagnet 425. . Accordingly, the switch 424 is blocked, and the switch 426 remains blocked.

Then, as the external physical force is removed in the fourteenth section T14, the switch 426 is turned on and the switches 421 and 424 remain blocked. That is, in the fourteenth period T14, the power input terminal Pi and the load terminal Lo are electrically disconnected from each other, so that the individual switching unit 420 is cut off and maintains the state.

On the other hand, although not shown in FIG. 6, instead of blocking the switch 422 or the switch 428 in the ninth section T and the thirteenth section T13, the electric wire 420 is wound around the electromagnet 425. The current provided to the coil may be cut off and the individual switching unit 420 may be cut off.

This disconnection state of the individual switching unit 420 may be applied by applying physical force to the switches 421 and 426 even if power is subsequently supplied again, that is, even if the central switching unit 300 changes from the disconnection state to the conduction state. Since it is maintained until before, no power is supplied from the power input Pi to the load terminal Lo.

Referring now to Figures 7 and 8 will be described in detail for the individual switching unit according to another embodiment of the present invention.

FIG. 7 is a diagram illustrating an individual switching unit according to another embodiment of the present invention, and FIG. 8 is a diagram illustrating an operation of the individual switching unit illustrated in FIG. 7.

Referring to FIG. 7, the individual switching unit 430 according to another embodiment of the present invention is also connected between the power input terminal Pi and the load terminal Lo.

The individual switching unit 430 includes a switch 433 including one end 431 and the other end 432, an electromagnet 434, and an elastic member 435.

The switch 433 is symmetrically interlocked with one end 431 and the other end 432 with respect to the fixed shaft 43. One end 431 of the switch 433 is in selective contact with one end 31 of the power inlet end Pi, and the other end 432 of the switch 433 is in selective contact with the one end 34 of the electromagnet 434. do.

A plurality of coils are wound around the electromagnet 434 and include one end 34 in contact with the other end 432 of the switch 433. The coil is connected to one end 34.

The elastic member 435 is connected to the other end 432 of the switch 433 based on the fixed shaft 43, and provides a resilient elastic force when a physical force is applied to the other end 432 of the switch 433. When the force is removed, it provides restoring elasticity.

Referring to FIG. 8, when a physical force is applied to the other end 432 of the switch 433, the other end 432 of the switch and one end 34 of the electromagnet 434 contact each other, and the one end 431 of the switch and the power supply. One end 31 of the leading end Pi contacts. Then, a current flows through the coil wound around the electromagnet 434, and a magnetic force stronger than the restoring elastic force provided by the elastic member 435 is generated in the electromagnet 434. As a result, the other end 432 of the switch 433 maintains a contact state with the one end 34 of the electromagnet 434. This state is maintained as long as power is supplied from the power inlet Pi.

At this time, the strength of the magnetic force supplied by the electromagnet 434 is proportional to the number of windings of the coil, the number of windings is determined to withstand the restoring elastic force of the elastic member 435. In addition, the restoring elastic force of the elastic member 435 is determined not to exceed the magnetic force by the residual magnet 434.

When the other end 432 of the switch 433 is released from the one end 34 of the electromagnet 434, the magnetic force is stopped and the switch 433 is turned on by the restoring elastic force of the elastic member 435. Then, the power input terminal Pi and the load terminal Lo are electrically disconnected from each other, so that the individual switching unit 430 is cut off and maintained.

This operation may occur by applying an external physical force to one end 431 of the switch 433, or may be caused by the user discontinuing supply of power to the power input terminal Pi.

This blocking state of the individual switching unit 430 may be applied until the power is applied again, that is, even if the central switching unit 300 changes from the blocking state to the conducting state, until the switch 433 is energized. Since power is maintained, power is not supplied from the power input terminal Pi to the load terminal Lo.

Referring now to Figures 9 and 10 will be described in detail for the individual switching unit according to another embodiment of the present invention.

9 is a view showing an individual switching unit according to another embodiment of the present invention, Figure 10 is a view showing the operation of the individual switching unit shown in FIG.

Referring to FIG. 9, the individual switching unit 440 according to another embodiment of the present invention is also connected between the power input terminal Pi and the load terminal Lo.

Individual switching unit 440 includes switches 441 and 442, electromagnets 444 and elastic members 445 and 446.

One end of the switch 441 is connected to the power input terminal Pi, and the other end of the switch 441 is connected to the switch 442. The center of the switch 441 is connected to the elastic member 446.

One end of the switch 442 is connected to the switch 442, and the other end of the switch 442 selectively contacts the one end 44 of the electromagnet 444. The center of the switch 442 is connected to the elastic member 445.

A plurality of coils are wound around the electromagnet 444 and include one end 44 in contact with the switch 442. The coil is connected to one end 44.

The elastic member 445 provides a resilient elastic force when a physical force is applied to the switch 442, and provides a resilient elastic force when the physical force is removed. As a result, the switch 442 remains in a blocked state when there is no physical force and remains in a conductive state only when there is a physical force.

The elastic member 446 provides a resilient elastic force when a physical force is applied to the switch 441 and a resilient elastic force when a physical force of the switch 441 is removed. As a result, the switch 441 remains in the conducting state when there is no physical force, and remains in the blocked state only when the physical force is applied.

Referring to FIG. 10, when a physical force is applied to the switch 442, the switch 442 and one end 44 of the electromagnet 444 contact each other. Then, a current flows through the coil wound around the electromagnet 444, and a magnetic force stronger than the restoring elastic force provided by the elastic member 445 is generated in the electromagnet 444. As a result, the switch 442 is in contact with the one end 44 of the electromagnet 444. This state is maintained as long as power is supplied from the power inlet Pi.

Applying a physical force to switch 441 stops the current provided to the coil and stops the generation of magnetic force in electromagnet 444. Then, the contact state between the switch 442 and the one end 44 of the electromagnet 444 is released by the restoring elastic force of the elastic member 445. This operation may occur by the user interrupting the power supply to the power input terminal Pi. Then, the power input terminal Pi and the load terminal Lo are electrically disconnected from each other, so that the individual switching unit 430 is cut off and maintained.

This disconnection state of the individual switching unit 440 may be applied by applying physical force to the switches 441 and 442 even if power is subsequently supplied again, that is, even if the central switching unit 300 changes from the disconnection state to the conduction state. Since it is maintained until before, no power is supplied from the power input Pi to the load terminal Lo.

The embodiments of the present invention described above are not only implemented through the apparatus and the method, but may be implemented through a program for realizing a function corresponding to the configuration of the embodiments of the present invention or a recording medium on which the program is recorded.

Although the embodiments of the present invention have been described in detail above, the scope of the present invention is not limited thereto, and various modifications and improvements of those skilled in the art using the basic concepts of the present invention defined in the following claims are also provided. It belongs to the scope of rights.

1 is a block diagram of a network system according to an embodiment of the present invention.

2 is a flowchart illustrating an operation of an individual switching unit according to an exemplary embodiment of the present invention.

3 is a circuit diagram illustrating an individual switching unit according to an embodiment of the present invention.

4 is a state diagram showing an open / close state of the individual switching units shown in FIG. 3.

5 is a circuit diagram illustrating an individual switching unit according to another embodiment of the present invention.

FIG. 6 is a state diagram showing the opening and closing states of the individual switching units shown in FIG. 5.

7 is a diagram illustrating an individual switching unit according to another embodiment of the present invention.

8 is a view for explaining the operation of the individual switching unit shown in FIG.

9 is a view showing an individual switching unit according to another embodiment of the present invention.

10 is a view showing the operation of the individual switching unit shown in FIG.

Claims (29)

An apparatus for controlling power sources of a plurality of electronic devices, A central switching unit which temporarily blocks all power connected to the plurality of electronic devices by temporarily interrupting and automatically turning on the power supply after being interrupted by external operation or physical force, and Each switching unit controls power connected to the plurality of electronic devices, and cuts off the power connected to the plurality of electronic devices when the central switching unit is turned off, and maintains the cutoff state. Power control device comprising a. In claim 1, If the individual switching unit is in a conductive state before the central switching unit is shut off, the individual switching unit is shut off after the central switching unit is shut off and then turned on. When the individual switching unit is in a blocking state before the central switching unit is shut off, the individual switching unit maintains a blocking state after the central switching unit is shut off and conducting. Power control unit. In claim 1, And after the central switching unit cuts off all power connected to the plurality of electronic devices, the individual switching unit is turned on when it is necessary to use some of the plurality of electronic devices. 4. The method of claim 3, And the individual switching unit is cut off after the use of the electronic device is terminated. In claim 1, And the individual switching unit is connected between the central switching unit and the plurality of devices. In claim 1, The individual switching unit, A first switch connected between the power input end and the load end, A relay connected between the power input terminal and the load terminal and connected in parallel with the first switch; and A second switch connected between the first switch and the relay Power control device comprising a. In claim 6, And the relay includes a third switch facing each other and an electromagnet wound around a coil connected to the second switch. 8. The method of claim 7, And the first switch maintains a closed state when no physical force is applied, and the second switch maintains a conducting state when no physical force is applied. In claim 8, When the current flows in the coil, the electromagnet generates a magnetic force, And the third switch maintains a blocked state when the magnetic force is not generated. The method of claim 9, When the first switch is changed from the cutoff state to the conductive state, the third switch is changed from the cutoff state to the conductive state, When the second switch is changed from the conduction state to the cutoff state or when the power drawn into the power input end is cut off, the third switch is changed from the conduction state to the cutoff state. Power control unit. In claim 1, The individual switching unit, A first switch connected between the power input end and the load end, A relay connected between the power input terminal and the load terminal and connected in parallel with the first switch; A second switch connected to the relay, A third switch connected in parallel with the first switch, A third switch connected between the power input terminal and the load terminal and connected in parallel with the first switch, and A fourth switch connected between the load end and the second switch Power control device comprising a. 12. The method of claim 11, And the relay includes a fifth switch facing each other and an electromagnet on which coils connected to the second switch are wound. The method of claim 12, And the first and third switches remain closed when no physical force is applied, and the second and fourth switches remain in a conductive state when no physical force is applied. The method of claim 13, When the current flows in the coil, the electromagnet generates a magnetic force, And the fifth switch maintains a blocked state when the magnetic force is not generated. The method of claim 14, When the first switch is changed from the cutoff state to the conductive state, the fifth switch is changed from the cutoff state to the conductive state, When the second switch is changed from the conduction state to the disconnection state, the fifth switch is changed from the conduction state to the disconnection state Power control unit. The method of claim 14, When the third switch is changed from the cutoff state to the conductive state, the fifth switch is changed from the cutoff state to the conductive state, When the fourth switch is changed from the conduction state to the cutoff state or when the power input to the power input end is cut off, the fifth switch is changed from the conduction state to the cutoff state. Power control unit. In claim 1, The individual switching unit, Electromagnet with coil wound A switch symmetrically interlocked with respect to the fixed shaft, the switch including one end selectively contacting the power inlet end and the other end selectively contacting the coil, and An elastic member connected to the other end of the switch with respect to the fixed shaft Power control device comprising a. The method of claim 17, And when the physical force is applied to the other end of the switch, the elastic member provides a resilient elastic force to the switch, and provides a resilient elastic force to the switch when the physical force is removed. The method of claim 17, When a physical force is applied to the other end of the switch, the other end of the switch and the coil and the one end of the switch and the power lead wire, the magnetic force is generated in the electromagnet, Contact between the other end of the switch and the coil is maintained by the magnetic force, When a physical force is applied to one end of the switch, the contact between the other end of the switch and the coil is released and the contact between the one end of the switch and the power lead is released to remove the magnetic force. Power control unit. In claim 1, The individual switching unit, Electromagnet with coil wound A first switch in selective contact with the coil, A first elastic member connected to the first switch, A second switch connected between a power inlet and the first switch, and A second elastic member connected to the second switch Power control device comprising a. The method of claim 20, And the first elastic member provides a resilient elastic force to the first switch to maintain the first switch in a blocked state when no physical force is applied to the first switch. The method of claim 20, And the second elastic member provides a restoring elastic force to the second switch to maintain the conductive state when no physical force is applied. The method of claim 20, When a physical force is applied to the first switch, the first switch is turned on, a magnetic force is generated in the electromagnet to maintain the conduction state of the first switch, When a physical force is applied to the second switch, the second switch is blocked so that the magnetic force is removed and the first switch is blocked. Power control unit. A first switch connected between the power input end and the load end, A relay connected between the power input terminal and the load terminal and connected in parallel with the first switch; and A second switch connected between the first switch and the relay Including, And the first switch maintains a closed state when no physical force is applied, and the second switch maintains a conducting state when no physical force is applied. The method of claim 24, The relay includes a third switch facing each other and an electromagnet wound around a coil connected to the second switch, When the current flows in the coil, the electromagnet generates a magnetic force, And the third switch maintains a blocked state when the magnetic force is not generated. A first switch connected between the power input end and the load end, A relay connected between the power input terminal and the load terminal and connected in parallel with the first switch; A second switch connected to the relay, A third switch connected in parallel with the first switch, A third switch connected between the power input terminal and the load terminal and connected in parallel with the first switch, and A fourth switch connected between the load end and the second switch Including, And the first and third switches remain closed when no physical force is applied, and the second and fourth switches remain in a conductive state when no physical force is applied. The method of claim 26, The relay includes a fifth switch facing each other and an electromagnet wound around a coil connected to the second switch, When the current flows in the coil, the electromagnet generates a magnetic force, The fifth switch maintains a blocked state when the magnetic force is not generated Power control unit. Electromagnet with coil wound A switch symmetrically interlocked with respect to the fixed shaft, the switch including one end selectively contacting the power inlet end and the other end selectively contacting the coil, and It is connected to the other end of the switch on the basis of the fixed shaft, when the other end of the physical force is applied to the switch provides a resilient elastic force, and when the physical force is removed the restoring elastic force to the switch Providing elastic member Power control device comprising a. Electromagnet with coil wound A first switch in selective contact with the coil, A first elastic member connected to the first switch and providing a resilient elastic force to the first switch to maintain the first switch in a blocked state when no physical force is applied to the first switch; A second switch connected between a power inlet and the first switch, and A second elastic member connected to the second switch and providing a resilient elastic force to the second switch to maintain the conductive state when no physical force is applied; Power control device comprising a.

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