JP6164984B2 - Power switching system at power failure - Google Patents

Description

  The present invention relates to a system that can switch between a commercial power supply line and an external power supply line and use an external power supply when the commercial power supply is stopped.

Not only during disasters such as earthquakes, but also during planned power outages, during construction, etc., commercial power supplied by electric power companies is often stopped, making it impossible to use electricity. A system in which an external power source such as a generator power source can be used instead of a commercial power source in such a case has already been proposed as described in Patent Document 1.
Recently, there has been a large-scale disaster such as the Great East Japan Earthquake, and there is concern about whether the facilities that serve as shelters can function sufficiently.
The first thing that is required for such facilities in terms of electricity is lighting, but large facilities such as gymnasiums cannot be brightened entirely by illuminating with a lamp or the like. However, in the system described in Patent Document 1, By using an external power supply instead of a commercial power line, the existing mercury lamp can be used to brighten the whole and give the refugees a minimum sense of security.

JP 2010-142102 A

By the way, since an external power supply is supplied to the power supply line, a single-phase AC 100V outlet can also be used. Therefore, the electric equipment can be effectively used. However, since the capacity of the external power supply is limited, if the evacuees use the outlet without restriction, the power may be cut off and the lighting may be turned off.
On the other hand, if the power supply cannot be used at all, it is difficult to effectively use the electric equipment, and it is difficult to say that the function as a shelter can be sufficiently achieved.
The present invention has been made paying attention to the above-mentioned conventional problems, and when the capacity increases, only the power line for connection to the electrical equipment is automatically cut off, and the power supply to the lighting etc. is stable. It is an object of the present invention to provide a new and useful power supply switching system during a power failure that is devised so as to be maintained.

The present invention has been made to solve the above-mentioned problems, and the invention of claim 1 includes a power source switching means for selectively switching between a commercial power line and an external power line to connect the switched power line. Two or more power supply lines branched from the power line after the switching and connected to a load, a switch interposed in at least one of the power supply lines, and an interposition of the switch serve as a selective cutoff comprising a current detector for detecting a current flowing through the feed line, and a switching control unit that the detected current value is blocking the selective tripping power supply line by opening the switch when higher than the predetermined value, the open-close control The means comprises a meter relay connected to the current detection means, a power supply relay and a power cutoff relay interposed in the external power line, and the meter relay has a current value of the predetermined value. The power cut-off relay is operated when the power is high, the power cut-off relay is configured to stop the power supply relay and open the switch, and the excitation circuit of the power cut-off relay includes a self-holding contact and a reset button it is a power failure when the power switching system comprising: a.

The invention according to claim 2 is the power supply switching system at the time of power failure according to claim 1 , wherein the power supply line for selective interruption is branched in the middle from the power source for the commercial power line and the external power line. The breaker switch is interposed in the branch line on the external power supply line side, and the switch is also inserted in the branch line on the commercial power supply line side. A power supply switching system at the time of a power failure, characterized in that another power supply relay that operates by supply is provided and the switch is closed by the operation of the power supply relay.

According to a third aspect of the present invention, in the power switching system at the time of power failure described in the second aspect , the shutoff notification lamp is interposed in the external power supply line, and the shutoff notification lamp is turned on when the power shutoff relay is activated. This is a power switching system during a power failure.

According to a fourth aspect of the present invention, there is provided a power failure switching power supply system according to any one of the first to third aspects, wherein a display unit for displaying a current value is provided.

According to a fifth aspect of the present invention, in the power failure switching system according to any one of the first to fourth aspects, the power supply switching during a power failure is characterized in that the output terminal of the power supply line for selective interruption is constituted by an AC 100V outlet. System.

According to a sixth aspect of the present invention, in the power failure switching system according to any one of the first to fifth aspects, the external power source is a single-phase three-wire system.

  According to the power switching system at the time of power failure of the present invention, it is possible to automatically stop the power supply to an outlet or the like and prevent the capacity of the external power supply from being exceeded.

BRIEF DESCRIPTION OF THE DRAWINGS It is a block diagram of the whole power supply switching system at the time of a power failure which concerns on embodiment of this invention. FIG. 2 is a single line connection diagram of FIG. 1. It is a circuit diagram of the operation side power supply of the switching part of the commercial power supply line and generator power supply line of FIG. It is a circuit diagram of the generator power line of FIG. It is a circuit diagram of the generator power line of FIG. It is a circuit diagram of the electric power feeding line of FIG. It is explanatory drawing of the power supply state at the time of normal time (at the time of commercial power supply use) of the system of FIG. It is explanatory drawing of the power supply state at the time of the power failure of the system of FIG. 1 (at the time of generator power supply use).

A power failure switching system 1 according to an embodiment of the present invention will be described with reference to the drawings.
A power failure switching system 1 shown in FIG. 1 is installed in a junior high school. This power switching system 1 at the time of a power failure includes an outdoor relay box 3 installed outdoors, a control box 5 installed indoors, and a dedicated distribution board 7. Considering that mercury lamps with good luminous efficiency are widely used in gymnasiums, this power switching system 1 during a power failure is dedicated to a single-phase three-wire system.

Hereinafter, a specific configuration for realizing this will be described. A generator is used as an external power source.
As shown in the single-line diagram of FIG. 2, the generator power line G extends to the indoor control box 5 via the outdoor relay box 3, and one commercial power line AC is also connected to the control box 5 via the existing power board. It extends to.
In the control box 5, either the commercial power line AC or the generator power line G is connected to the switched power line E, and the switched power line E extends to the dedicated distribution board 7.

A power line in the power switching system 1 during a power failure will be roughly described with reference to the single-line diagram of FIG.
The commercial power supply line AC is a single-phase three-wire system, and extends to the control box 5 through the commercial breaker (NFB) in the existing power board and through the leakage breaker (ELB1) in the dedicated distribution board 7. The switch 9 is connected to one of the two input side connection portions of the switch 9. Further, an illumination line branches off from the commercial power supply line AC and extends to the outdoor relay box 3, and a lighting circuit for a commercial display lamp (PL6) arranged there is configured.
On the other hand, the generator power line G is also a single-phase three-wire system, and enters the outdoor relay box 3 by cable connection from the generator, passes through a commercial breaker (NFB) arranged there, and extends to the control box 5. The earth leakage breaker (ELB1) and the electromagnetic contactor type switch (MC1) arranged there are connected to the other input side connection portion of the switch 9 described above. In addition, the outdoor relay box 3 is provided with a branch circuit of an illumination line, and is configured such that the generator display lamp (PL4) is lit by power supply.

The output side connection portion of the switch 9 is connected to the power line E after switching. The power line E after switching is passed through the earth leakage breaker (ELB2) arranged in the dedicated distribution board 7 and further connected to the branch breaker. And are branched to power supply lines e1, e2,.
The power supply line e1 is for single-phase 200V, and is directly connected to a mercury lamp arranged on the ceiling as it comes out of the dedicated distribution board 7. The power supply line e2 is for single-phase 100V and is returned to the control box 5, where it merges after bifurcating in the middle, and its output terminal is a power outlet. In addition, electromagnetic contactor type switches (MC2, MC3) are interposed in the bifurcated branch line, respectively.

The above-described power supply line will be described in detail based on the three-phase connection diagram, centering on the inside of the control box 5 and the dedicated distribution board 7.
The commercial power supply line AC is composed of a single-phase three-wire R phase, S phase, and T phase. The S phase is grounded, AC 100V between the R phase and S phase and between the T phase and S phase, and AC 200V between the R phase and T phase. The generator power supply line G is a single-phase three-wire system and is composed of an R phase, an H phase, and a T phase, and the H phase is grounded.

As shown in FIG. 3, a commercial lamp (PL5), a return buzzer (BZ), a return buzzer OFF timer (T2) are supplied from the power input side to the R phase and S phase of the operation power supply for the switch of the commercial power line AC. ) Are connected to each other to form a branch circuit. A return buzzer (BZ) is interposed in the branch circuit of the timer switch (T2), and the return buzzer (BZ) is turned off when the return buzzer OFF timer (T2) is activated. Further, both terminals of the commercial energizing relay (R5) and the outlet power cut-off relay (MC3) are connected to form a branch circuit.
Further, both control terminals A1 and A2 for control of the switch 9 are connected to constitute a control circuit, and a make switch contact (R5) of the changeover switch is interposed on the input side.

On the other hand, a generator energization relay (R4) is interposed between the R phase and the H phase of the operation power supply of the generator power line G. Further, the control terminals of the switch 9 are connected to both terminals B1 and B2 to form a control circuit, and a break contact (R5) of the changeover switch is interposed on the input side thereof.
Further, between the break contact (R5) and the switch 9, a generator energization contact (R4) that is closed by the operation of the generator energization relay (R4) is interposed.

  As shown in FIG. 4, the generator power supply line G passes through the leakage breaker (ELB1) in the control box 5 and then is connected to the R phase and the H phase at both ends of the generator capacity abnormality relay (R2). The excitation circuit is configured by connecting the terminals. This excitation circuit is provided with a generator power cutoff contact (KM50) that is opened by the operation of a relay built in a power amount detection device (KM50) having a current transformer (CT1, CT2) as current detection means. When the amount of electric power exceeds an allowable value, the contact is closed and the generator capacity abnormality relay (R2) is activated. Moreover, since the detected electric energy is displayed on the electric energy monitor 11, it can be visually recognized.

Further, toward the output side, a generator lamp (PL1), a generator power supply delay (T1), a generator power supply relay (MC1), a generator capacity abnormality relay (R1), a generator capacity abnormality lamp (PL2) Each terminal on both ends of the generator emergency stop lamp (PL3) is connected to form a branch circuit.
In the branch circuit of the generator capacity abnormality relay (R1), a generator capacity abnormality contact (R2) and a self-holding contact (R1) that are closed by the operation of the generator capacity abnormality relay (R2) are interposed in parallel. Further, a reset contact (PB2) that is opened by pressing the reset button (PB2) is interposed in series with these. The branch circuit of the generator capacity abnormality lamp (PL2) is provided with a lighting contact (R1) that is closed by the operation of the generator capacity abnormality relay (R1).

Further, in the branch circuit of the generator power supply delay (T1), the delay contact (R1) opened by the operation of the generator capacity abnormality relay (R1) is connected to the contact (PB1) opened by pressing the emergency stop button (PB1). It is inserted in series. The branch circuit of the generator emergency stop lamp (PL3) is provided with a contact (PB1) that closes when the emergency stop button (PB1) is pressed.
The branch circuit of the generator power supply relay (MC1) is provided with a supply contact (T1) that is closed by the operation of the generator power supply delay (T1).

Furthermore, terminals on both ends of the outlet power supply relay (MC2), the outlet capacity abnormality relay (R3), and the outlet capacity abnormality lamp (PL7) are connected toward the output side to form a branch circuit.
The outlet capacity abnormality relay (R3) functions as an outlet power cut-off relay, and its branch circuit is abnormally closed by the operation of a meter relay (MR) provided with a current transformer (CT3) as current detection means described later. A contact (MR) and a self-holding contact (R3) are interposed in parallel, and a reset contact (PB3) that is opened by pressing the reset button (PB3) is interposed in series. The outlet capacity abnormality lamp (PL7) is provided with a lighting contact (R3) that is closed by the operation of the outlet capacity abnormality relay (R3).
In addition, the outlet power supply relay (MC2) has an outlet power cutoff contact (R3) that opens when the outlet capacity abnormality relay (R3) is operated, and an alternative opening and closing linked with the opening and closing of the commercial power supply side switch (MC3). A contact (MC3) is interposed in series.

  The switch 9 is configured by a power switching electromagnetic contactor, and when the input terminal A1 and the output terminal A2 are connected, the commercial power line AC and the switched power line E are connected, and the input terminal B1 When the output terminal B2 is connected, the generator power line G and the switched power line E are connected. In addition, a timer circuit (not shown) is provided so that the commercial power supply and the generator power supply do not overlap.

As shown in FIG. 6, a single-phase AC100V200V is output from the branch breaker, and the single-phase 200V power supply line e1 is connected to a mercury lamp.
The single-phase 100V power supply line e2 extends from the dedicated distribution board 7 and returns to the control box 5, where each phase line branches into two and then merges again. Consists of outlets. Then, both ends of the switch (MC2) are connected to one branch line of the R phase and one branch line of the N phase to constitute a switch circuit on the generator power supply side, and the other branch line of the R phase And the other branch line of the N phase are connected to both ends of the switch (MC3) to form a commercial power supply switching circuit.

The power switching system 1 at the time of a power failure has the above-described configuration, and operates as follows to supply power.
Since the commercial power is normally supplied, the commercial display lamp (PL6) of the outdoor relay box 3 and the commercial lamp (PL5) of the control box 5 are turned on. Further, the commercial energization relay (R5) is actuated to close the commercial energization contact (R5) of the switcher 9, and the commercial power supply line AC is switched to the post-switching power supply line E toward the dedicated distribution board 7 via the switcher 9. Connected. Further, since the commercial power is supplied, the switch relay (MC3) is operated, the switch (MC3) interposed in the power supply line e2 shown in FIG. 2 is closed, and both the power supply lines e1 and e2 are commercial power. Is supplied. Accordingly, since power is supplied to the power supply lines e1 and e2, the mercury lamp can be turned on, and an electric device can be connected to the power outlet for use.
At this time, since the alternative switching contact (MC3) is opened, the switch (MC2) is opened.

When the commercial power supply stops, the generator is used. Connect to the outdoor relay box 3 via a dedicated cable.
When the generator is operated and the generator power is supplied, the generator display lamp (PL4) of the outdoor relay box 3 of the generator power line G and the generator lamp (PL1) of the control box 5 are turned on. Further, the break contact (R5) is closed by stopping the commercial energization relay (R5), and the generator energization contact (R4) of the switch 9 is closed by the operation of the generator energization relay (R4). Then, it is connected to the power line E after switching from the generator power line G to the dedicated distribution board. Further, since the generator power is supplied, the switch relay (MC2) is operated and the switch (MC2) interposed in the power supply line e2 shown in FIG. 2 is closed, so both the power supply lines e1 and e2 are closed. Generator power is supplied.
At this time, since the switch relay (MC3) is kept stopped during a power failure, the switch (MC3) is opened and power is not supplied to both branch lines.

The generator capacity is monitored, and when the generator capacity abnormality relay (R2) is activated, the generator capacity abnormality relay (R1) is activated, and in conjunction therewith, the generator power supply delay (T1), the generator power supply The supply relay (MC1) is stopped, the switch (MC1) is opened, and the power supply is urgently stopped. At the same time, the generator capacity abnormality lamp (PL2) is turned on. The generator capacity abnormality relay (R1) is self-holding, but is reset by pressing the reset button (PB2), and power supply is resumed.
When the operator who has seen the power monitor 11 presses the emergency switch (PB1), the switch (MC1) is similarly opened due to the stop of the linked generator power supply delay (T1), and the power supply Supply is urgently stopped. At the same time, the generator emergency stop lamp (PL3) is turned on.

  The outlet power capacity is also monitored. If the meter relay (MR) is activated when the value is higher than a predetermined value, the outlet capacity abnormality relay (R3) is activated and the outlet power supply relay (MC2) is stopped in conjunction therewith. Then, the switch (MC2) is opened and only the power supply to the power supply line e2 is urgently stopped. At the same time, the outlet capacity abnormality lamp (PL7) is turned on. Although the outlet capacity abnormality relay (R3) is self-holding, it is reset by pressing the reset button (PB3), and the power supply is resumed. Since the current value is displayed on the display unit 13, it can also be visually recognized.

Therefore, as shown in FIG. 7, in general, commercial power is supplied uniformly not only to lighting equipment but also to electric equipment such as a television connected to an outlet as a general rule. On the other hand, as shown in FIG. 8, in the event of a power failure, generator power is supplied, but since power is also supplied to the power outlet, electrical equipment can also be used, but when the capacity is over, only the power outlet side is available. Is selectively shut off, so the mercury lamp on the ceiling will continue to light.
Further, when the commercial power supply is restored, the commercial energization relay (R5) is activated to open the generator energization contact (R5) of the switching device 9, and then the commercial energization contact (R5) is closed after a while. The commercial power supply line AC is connected to the post-switching power supply line E toward the dedicated distribution board 7 via the switch 9. Further, since the return buzzer (BZ) sounds for a certain period of time by the timer (T2), the recovery is informed to the surrounding people.

As described above, according to the power switching system 1 at the time of a power failure, since the power outlet can be used, the electrical equipment can be used, and only the power supply line to the power outlet is selectively cut off, so that the power source of the mercury lamp is stable. Secured.
Therefore, by introducing the power switching system 1 at the time of a power failure into a facility that serves as an evacuation site, the above-described facility can sufficiently perform the function required as the evacuation site.

  Although the embodiment has been described in detail above, the specific configuration is not limited to this embodiment, and any design change or the like within a scope not departing from the gist of the present invention is included in the invention.

DESCRIPTION OF SYMBOLS 1 ... Power supply switching system 3 at the time of a power failure ... Outdoor relay box 5 ... Control box 7 ... Exclusive distribution board 9 ... Switch AC ... Commercial power supply line G ... Generator power supply line E ... Power line MC after switching e ... Power supply line MC ... Electromagnetic Contactor R… Relay PL… Indicator lamp

Claims (6)

Power supply switching means for selectively switching between a commercial power supply line and an external power supply line and connecting the switched power supply line; two or more power supply lines branched from the switched power supply line and connected to a load; and the power supply A switch interposed in at least one of the lines, a current detection means for detecting a current flowing in a power supply line that is selectively cut off by the switch, and a detected current value is higher than a predetermined value Opening and closing control means for opening the switch sometimes to cut off the selective cutoff power supply line ,
The open / close control means includes a meter relay connected to the current detection means, a power supply relay and a power cutoff relay interposed in the external power line, and the meter relay has a current value of the predetermined value. The power cut-off relay is operated when higher, the power cut-off relay is configured to stop the power supply relay and open the switch, and the excitation circuit of the power cut-off relay includes a self-holding contact and a reset button A power switching system at the time of power failure characterized by comprising: In the power failure switching system according to claim 1,
The power supply line for selective interruption is branched in the middle from the power source for the commercial power line and the external power line, and the switch for selective interruption is interposed in the branch line on the external power line side, and The branch line on the commercial power line side is also provided with a switch, and the commercial power line side includes another power supply relay that operates by supplying power to the commercial power line. A power switching system during a power failure, characterized in that the switch is closed . In the power failure switching system according to claim 2 ,
A power switching system during a power failure , wherein a shutoff notification lamp is interposed in an external power supply line, and the shutoff notification lamp is turned on when a power shutoff relay is activated . In the power failure switching system according to any one of claims 1 to 3 ,
A power supply switching system during a power failure, wherein a display unit for displaying a current value is provided . In the power failure switching system according to any one of claims 1 to 4,
A power switching system at the time of power failure, wherein the output terminal of the power supply line for selective interruption is constituted by an AC 100V outlet . In a power failure switching system according to any one of claims 1 to 5,
A power switching system during a power failure, wherein the external power source is a single-phase three-wire system.

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