KR20230147999A - Distribution board with selective fire indication by synthesizing dc multi-power potential - Google Patents

Abstract

The distribution board with a selective fire indication function by direct current multi-power potential synthesis according to the present invention is a distribution board that supplies emergency power to loads including electrical equipment arranged in a plurality of buildings, and provides emergency power in the event of a fire or power outage. an emergency overload wiring blocking main circuit configured to be turned on to the load side through the automatic transfer switch, and configured to cut off the emergency power when the load reaches an overload state; an emergency overload detection circuit configured to display a malfunction for the building when a fire occurs in one or more of the plurality of buildings; A constant power priority operation control circuit that excites the first relay coil using constant power; and a fire monitoring composite circuit that excites the second relay coil using the firefighting power source of the building when a fire occurs in one or more of the plurality of buildings.

Description

Distribution board with selective fire indication function by direct current multi-power potential synthesis {DISTRIBUTION BOARD WITH SELECTIVE FIRE INDICATION BY SYNTHESIZING DC MULTI-POWER POTENTIAL}

The present invention relates to a distribution board with a selective fire display function by synthesizing the potential of DC multi-power sources. More specifically, it relates to a distribution board that can classify and display and manage abnormal conditions such as fires in each building of a multi-family house or apartment complex, etc. This relates to a distribution board with a selective fire indication function by potential synthesis.

In general, apartment complexes are equipped with automatic fire detection equipment to notify in the event of a fire. Such automatic fire detection equipment recognizes whether a fire has occurred by detecting the heat, smoke, or flame generated by the fire using a sensor, and provides a fire alarm to the manager and household members of the apartment complex through sound devices such as a bell or siren. It is a facility that emits light and generally consists of a receiver, detector, transmitter, sound device, etc.

Fire receivers used in fire management receive signals emitted from detectors or transmitters as common signals directly or through repeaters and alert the manager of the fire-fighting object or the fire department of the occurrence of a fire. These are P-type receivers and R-type receivers. , M-type receiver, GP-type receiver, GR-type receiver, etc.

Meanwhile, signals emitted from detectors or transmitters (excluding M-type transmitters) are received directly or through a repeater as a common signal to alert the manager of the fire-fighting object in question and automatically or manually fire extinguishing equipment and sprinklers indoors and outdoors. There is a P-type complex receiver that controls pressurized water transmission devices or starting devices such as equipment, water spray fire extinguishing equipment, foam fire extinguishing equipment, carbon dioxide fire extinguishing equipment, halogenated fire extinguishing equipment, powder fire extinguishing equipment, and smoke exhaust equipment.

In addition, there are R-type complex receivers, GP-type complex receivers, and GR-type complex receivers.

P-type (Proprietary type) receivers are most often used in small and medium-sized buildings due to their ease of installation and cost per unit of equipment. They are equipped with district indicator lights that indicate the boundary area for each circuit, and are classified into class 1 and 1 depending on performance. It is classified into level 2.

The P-type class 1 receiver is capable of fire indication operation, detector wiring continuity test, and switching between commercial power and emergency power, and has the advantage of having no limit on the number of circuits. The P-type class 2 receiver has the same structure as the P-type class 1 receiver. It is the same, but the number of lines is limited to 5 or less.

Recently, with the rapid spread of information communication technology (ITC), most buildings currently being built are changing into intelligent buildings and intelligent apartments.

Accordingly, there is a problem in the field of firefighting equipment that makes it difficult to adapt to current trends with outdated technologies of the past.

In particular, automatic fire detection equipment (AFDE) is mandated as a 'firefighting technology standard' to be installed in neighborhood living facilities, educational and research facilities, entertainment facilities, lodging facilities, medical facilities, and buildings larger than 600㎡. It is stipulated that buildings with 4 or more floors must use P-type Class 1 receivers.

However, the control algorithm and fire suppression control system of the automatic fire detection equipment currently in use are based on technologies that have been in use since the 1970s.

Figure 6 is an outline diagram of a conventional automatic fire detection equipment, and Figure 7 is a wiring diagram of a conventional automatic fire detection equipment.

Referring to FIGS. 6 and 7, the automatic fire detection equipment is a facility that automatically detects heat and smoke generated in the initial stage when a fire or disaster occurs, displays the location of ignition to personnel in the building, and simultaneously issues an alarm. , a detector that detects smoke or gas, a receiver that specifies the location of ignition, a transmitter, a sound device, wiring, and a power source.

Figure 8 is a signal flow system diagram in a conventional automatic fire detection equipment.

Referring to FIG. 8, in the conventional automatic fire detection equipment (P-type class 1 receiver), when a fire or disaster occurs (10), the disaster detection sensors (11, 12, 13) operate and the receiver (14) detects this to provide an alarm emergency. It is a unidirectional algorithm that operates the broadcasting system (15) and the warning display board (16) and operates the locally installed disaster prevention equipment (17, 18) such as sprinklers and fire doors.

When an actual fire occurs in such a conventional P-type Class 1 receiver, the response speed and reliability are poor, resulting in increased casualties and property damage, and there is a problem of inefficiency in disaster response due to a unilateral control algorithm in the event of a fire or disaster.

As a prior art to solve such conventional problems, Korea Patent No. 10-1364813 (registered on February 12, 2014) “Smart Fire Disaster Prevention System” (hereinafter referred to as ‘prior art’) is known.

The above prior art is electrically connected to a detection sensor module for detecting fires and disasters, a disaster prevention device for warning or suppressing fires and disasters, a detection sensor module, and a disaster prevention device, and receives detection signals detected from the detection sensor module. When a detection signal is received from a fire detection facility that handles fire detection, a computer for remotely monitoring the site where a fire or disaster occurs, and a fire detection facility, the disaster prevention device is activated through the fire detection facility, and the detection signal is received through a computer and a wired or wireless communication network. It includes a control module that transmits fire and disaster occurrence situation information to the computer and, upon receiving a control command from the computer, controls the operation of the disaster prevention device according to the received control command, and applies a bidirectional algorithm through a wired and wireless communication network. Provides a smart fire-fighting disaster prevention system.

However, this fire-fighting disaster prevention system is difficult to apply to apartment buildings where several buildings are connected by a single fire detection system. It can be applied when the computer is located in a remote location and there are no problems with power supply due to fire, or when the computer is located in an apartment building. There is no solution in case the power supply to the computer is temporarily lost.

Registered Patent No. 1364813 Smart Fire Protection Disaster Prevention System Registered Patent No. 1868039: Fire alarm alarm device using communication facilities of apartment complex Registered Patent No. 2165093 Building fire monitoring firefighting system Registered Patent No. 2283884 Artificial intelligence-based electrical fire prediction and predictive maintenance system and method

The purpose of the present invention is to provide a distribution board with a selective fire display function through direct current multiple power source potential synthesis that can classify and display abnormal conditions such as fires in each building of a multi-family house or apartment complex.

In addition, the present invention provides a distribution board with a selective fire display function by combining DC multi-power potentials, which can block the supply from the emergency power source to the load when an overload condition occurs in the emergency power source connected to multiple buildings, and has another purpose. There is.

The problems to be solved by the present invention are not limited to those mentioned above, and other problems not mentioned will be clearly understood by those skilled in the art from the description below.

The distribution board with a selective fire indication function by direct current multi-power potential synthesis according to the present invention is a distribution board that supplies emergency power to loads including electrical equipment arranged in a plurality of buildings, and provides emergency power in the event of a fire or power outage. an emergency overload wiring blocking main circuit configured to be turned on to the load side through the automatic transfer switch, and configured to cut off the emergency power when the load reaches an overload state in the event of a fire or power outage; an emergency overload detection circuit configured to display a malfunction for the building when a fire occurs in one or more of the plurality of buildings; A constant power priority operation control circuit that excites the first relay coil using constant power; and a fire monitoring composite circuit that excites the second relay coil using the firefighting power source of the building when a fire occurs in one or more of the plurality of buildings.

Preferably, the emergency overload wiring blocking main circuit includes: a wiring breaker disposed between a hot line connected to an automatic transfer switch and the third relay switch below; a third relay switch connected between the other end of the molded circuit breaker and one end of a first relay switch, the first relay switch being interlocked with the first relay coil; And a second relay switch connected in parallel with the first relay switch and the other end of which is connected to a ground line connected to the automatic transfer switch - the second relay switch is linked to the second relay coil.

Preferably, the emergency overload detection circuit includes: an overload detection unit that outputs an overload detection signal when load power consumed by the load exceeds a predetermined range; a second rectifier that rectifies the emergency power output from the emergency generator when the overload detection signal is output; a second constant voltage unit converting the rectified voltage output from the second rectifier into a predetermined constant voltage; an overload detection display unit that emits light according to the output of the second constant voltage unit; a third relay coil excited according to the output of the second constant voltage unit; and a reverse current prevention unit that prevents reverse current from the third relay coil to the second constant voltage unit.

Preferably, the fire monitoring composite circuit includes first to Nth fire detection units (where N is 2 or more) disposed in each of the plurality of buildings, and each of the first to Nth fire detection units is , a fire detection switch connected in series to the fire power supply; a reverse charge prevention unit disposed between the fire-fighting power source and the first relay coil; and a fire display unit disposed between the fire monitoring switch and the other end of the first relay coil and emitting light in the event of a fire in the building.

Preferably, the constant power priority operation control circuit includes: a first LED that emits light when constant power is applied; A photocoupler light emitting unit connected in parallel with the constant power source and emitting light when the constant power source is applied; A photocoupler light receiving unit disposed between the power voltage terminal and the ground terminal and linked to the operation of the photocoupler light emitting unit; a switching voltage application unit disposed between the photocoupler light receiving unit and a ground terminal and maintaining a switching voltage at a predetermined level when the photocoupler light receiving unit is turned on; a first switching unit disposed between the power voltage terminal and the ground terminal and switching by receiving the switching voltage output from the switching voltage application unit to a control terminal; and a second relay coil disposed between the power voltage terminal and the first switching unit and excited when the first switching unit is turned on.

Preferably, the third relay switch is connected to the molded circuit breaker through a b contact, the first relay switch is connected to the third relay switch through an a contact, and the second relay switch is connected to the third relay switch through a b contact. It is characterized by being connected to a relay switch.

In addition, the distribution board with a selective fire indication function by direct current multi-power source potential synthesis according to the present invention is a distribution board that supplies emergency power to loads including electrical equipment arranged in a plurality of buildings in the event of a fire or power outage. Emergency power is configured to be supplied to the load through an automatic transfer switch, and is configured to cut off the emergency power when the load reaches an overload state in the event of a fire or power outage, and when a fire occurs in one or more of the plurality of buildings, the Indicate a fire in the building.

According to the distribution board with a selective fire display function by direct current multi-power source potential synthesis of the present invention, it is possible to classify and display abnormal conditions such as fire in each building of a multi-family house or apartment complex, and to emergency power supplies connected to multiple buildings. If an overload condition occurs, the supply from the emergency power source to the load can be cut off.

1 is a constant voltage generation circuit diagram according to an embodiment of the present invention;
Figure 2 is a constant power priority operation control circuit diagram according to an embodiment of the present invention;
Figure 3 is a fire monitoring composite circuit diagram connected to multiple buildings according to an embodiment of the present invention;
4 is a circuit diagram of an emergency generator overload detection according to an embodiment of the present invention;
Figure 5 is a main circuit diagram for blocking emergency overload wiring according to an embodiment of the present invention;
Figure 6 is an outline diagram of a conventional automatic fire detection equipment;
Figure 7 is a wiring diagram of a conventional automatic fire detection equipment, and
Figure 8 is a signal flow system diagram in a conventional automatic fire detection equipment.

Additional objects, features and advantages of the present invention may be more clearly understood from the following detailed description and accompanying drawings.

Prior to a detailed description of the present invention, it should be noted that the present invention is capable of various modifications and may have various embodiments, and the examples described below and shown in the drawings are not intended to limit the present invention to specific embodiments. No, it should be understood to include all changes, equivalents, and substitutes included in the spirit and technical scope of the present invention.

When a component is said to be "connected" or "connected" to another component, it is understood that it may be directly connected to or connected to the other component, but that other components may exist in between. It should be. On the other hand, when it is mentioned that a component is “directly connected” or “directly connected” to another component, it should be understood that there are no other components in between.

The terms used in this specification are merely used to describe specific embodiments and are not intended to limit the present invention. Singular expressions include plural expressions unless the context clearly dictates otherwise. In this specification, terms such as “comprise” or “have” are intended to indicate the presence of features, numbers, steps, operations, components, parts, or combinations thereof described in the specification, but are not intended to indicate the presence of one or more other features. It should be understood that this does not exclude in advance the possibility of the existence or addition of elements, numbers, steps, operations, components, parts, or combinations thereof.

In addition, terms such as "... unit", "... unit", and "... module" used in the specification refer to a unit that processes at least one function or operation, which is hardware or software or hardware and It can be implemented through a combination of software.

In addition, when describing with reference to the accompanying drawings, identical components will be assigned the same reference numerals regardless of the reference numerals, and overlapping descriptions thereof will be omitted. In describing the present invention, if it is determined that a detailed description of related known technologies may unnecessarily obscure the gist of the present invention, the detailed description will be omitted.

1 is a circuit diagram of a constant voltage generation according to an embodiment of the present invention.

The constant voltage generator circuit according to an embodiment of the present invention includes a noise reduction unit 110, a first rectifier 120, and a first constant voltage unit 130, and converts the applied alternating voltage into a predetermined constant voltage. Print out.

Specifically, the noise reduction unit 110 reduces surge or noise included in the alternating current voltage applied from the outside through the hot line (L) and the ground line (N). Here, the reference symbol TNR refers to a varistor that absorbs surge voltage.

The first rectifier 120 rectifies the alternating current voltage passing through the noise reduction unit 110 into a rectified voltage. The first rectifier 120 may be composed of a bridge diode.

The first constant voltage unit 130 converts the rectified voltage output from the first rectifier 120 into a predetermined constant voltage. Here, the reference symbol ZD refers to a Zener diode that maintains the voltage constant.

Figure 2 is a constant power priority operation control circuit diagram according to an embodiment of the present invention.

The constant power priority operation control circuit disposed in the distribution board according to an embodiment of the present invention prevents regular power or emergency power from being supplied through an automatic transfer switch when regular power is supplied.

That is, the constant power supply control circuit disposed in the distribution panel according to one embodiment of the present invention excites the second relay coil 260 when constant power is applied.

Specifically, the constant power supply control circuit disposed in the distribution board according to an embodiment of the present invention includes a first LED (G) 210, a photocoupler light emitting unit 220 connected in parallel with the constant power supply, and a photocoupler light receiving unit ( 230), a switching voltage application unit 240, a first switching unit (Q1, 250), and a second relay coil 260.

The first LED(G) 210 turns on and emits light when constant power is applied.

The photocoupler light emitting unit 220 is connected in parallel with the constant power source, and when the constant power source is applied, it turns on and emits light.

The photocoupler light receiving unit 230 is disposed between a predetermined power voltage terminal and a ground terminal, and is turned on by receiving light emitted by the photocoupler light emitting unit 220.

The switching voltage application unit 240 includes a resistor (R6) and capacitors (C6, C7) disposed between the photocoupler light receiving unit 230 and the ground terminal, and when the photocoupler light receiving unit 230 is turned on, switching at a predetermined level. Maintain voltage.

The first switching unit (Q1, 250) is disposed between a predetermined power voltage terminal and a ground terminal, and includes a first transistor (Q1) that is turned on by receiving the switching voltage output from the switching voltage application unit 240 to the control terminal. Includes.

The second relay coil 260 is disposed between a predetermined power voltage terminal and the first switching unit 250, and is excited when the first switching unit 250 is turned on.

According to one embodiment of the present invention, a regular power source or an emergency power source is connected to an automatic transfer switch (ATS). At all times, regular power is supplied to the automatic transfer switch, and when the regular power is cut off and switched to emergency due to a power outage, emergency power from the emergency generator is supplied to the automatic transfer switch (ATS).

Figure 3 is a fire monitoring composite circuit diagram connected to multiple buildings according to an embodiment of the present invention.

In the fire monitoring composite circuit connected to multiple buildings according to an embodiment of the present invention, each of the first to Nth fire detection units (310, 320, ..., 3N0) disposed in individual buildings includes a first relay coil ( 330) and is connected in parallel.

The first to Nth fire detection units (310, 320, ..., 3N0) disposed in individual buildings are the first to Nth firefighting power sources (311, 321, ..., 3N1) and the first to Nth fire detection units (311, 321, ..., 3N1), respectively. Fire detection switches (313, 323, ..., 3N3), first to Nth reverse charge prevention units (315, 325, ..., 3N5), and first to Nth fire occurrence display units (317, 327, . .., 3N7).

The first to Nth fire detection units 310, 320, ..., 3N0 disposed in individual buildings operate as follows. For example, building 1 will be described. When a fire occurs in Building 1, the first fire detection switch 313 is closed, and the first fire power source 311 is applied to the first fire display unit 317 through the first reverse charge prevention unit 315. The first fire display unit 317 turns on and emits light. The fire detection unit operates in the same way for fires in the remaining buildings. In other words, when a fire occurs in an individual building, the fire display unit placed in the individual building operates independently of other buildings and displays the fire occurrence situation only within the building.

The first to Nth reverse charge prevention units (315, 325, ..., 3N5) are configured to switch from a relatively high voltage firefighting power source to a relatively low voltage fire source when a fire occurs in a plurality of buildings and a plurality of fire detection switches are closed. It is provided to prevent breakdowns such as overheating of the fire-fighting power source due to current flowing into the fire-fighting power source.

Meanwhile, the first relay coil 330 is connected in parallel with the first to Nth fire detection units 310, 320, ..., 3N0, so it can be excited even if a fire occurs in any building.

According to the present invention, one emergency generator is electrically connected to supply emergency power to multiple buildings. In other words, if a fire occurs in one of multiple buildings, the emergency generator supplies emergency power to that building. However, if a fire or power outage occurs not in one building but in multiple buildings, resulting in an overload situation where emergency power must be supplied, the range that the emergency generator can handle is exceeded. In this case, it is necessary to cut off the supply of emergency power from the emergency generator. To this end, when the overload detection unit 420 according to an embodiment of the present invention detects an overload state, it outputs an overload detection signal to excite the third relay coil 470, while when the overload state is not in the overload state, the overload detection unit 420 outputs an overload detection signal. Since it does not output, the third relay coil 470 maintains the deactivated state.

Figure 4 is an emergency overload detection circuit diagram according to an embodiment of the present invention.

The emergency overload detection circuit according to an embodiment of the present invention displays an overload detection by outputting an overload detection signal when an overload occurs in the power supplied by the emergency generator 410 to the load 480, and a third relay coil. Excite (470).

For this purpose, the emergency overload detection circuit includes an emergency generator 410, an overload detection unit 420, a second rectifier 430, a second constant voltage unit 440, a reverse current prevention unit 450, an overload detection display unit 460, and a third relay coil 470.

The emergency generator 410 supplies emergency power to the load 480 during a power outage.

When the load power consumed by the load 480 of the emergency generator 410 exceeds a predetermined range and the overload detection unit 420 outputs an overload detection signal, the second rectifier 430 rectifies and outputs the emergency power. The second rectifier 430 may be composed of a bridge diode. Here, the overload detection unit 420 is disposed on one side of the emergency generator 410.

The second constant voltage unit 440 converts the rectified voltage output from the second rectifier 430 into a predetermined constant voltage. Here, the reference symbol ZD refers to a Zener diode that maintains the voltage constant.

The overload detection display unit 460 includes an LED that is turned on and displayed in red, for example, according to the constant voltage output from the second constant voltage unit 440.

The third relay coil 470 is excited according to the constant voltage output from the second constant voltage unit 440.

The reverse current prevention unit 450 prevents reverse current from flowing from the third relay coil 470 to the second constant voltage unit 440.

Figure 5 is a main circuit diagram for blocking emergency overload wiring according to an embodiment of the present invention.

The emergency overload wiring blocking main circuit according to an embodiment of the present invention includes a molded case circuit breaker 510, first to third relay switches 520, 530, and 540, and a molded case circuit breaker contact point 550.

Specifically, the molded circuit breaker 510 is connected between a hot line connected to an automatic transfer switch (ATS) and the third relay switch 540.

The third relay switch 540 is connected between the other end of the molded circuit breaker 510 and one end of the first relay switch 520, and the second relay switch 530 is connected in parallel with the first relay switch 520. And the other end of the first relay switch 520 is connected to the ground line.

The molded circuit breaker contact point 550 is disposed between the automatic transfer switch (ATS) and the load (MC).

The first to third relay switches 520, 530, and 540 shown in FIG. 5 represent a state before power is supplied.

The first relay switch 520 is always connected to the b contact point, and in the event of a fire in an individual building, it is linked to the first relay coil 330, which is excited as the fire detection switch is closed, and switches to the a contact point to connect the circuit breaker 510. is excited, and the molded circuit breaker contact point 550 linked to the molded case circuit breaker 510 is closed, and emergency power (ATS 220V) is supplied to the load side (MC).

The second relay switch 530 is connected to contact A by exciting the second relay coil 260 when commercial power is applied, and switches to contact B during a power outage to excite the molded case circuit breaker 510. ) is closed and emergency power (ATS 220V) is supplied to the load side (MC).

The third relay switch 540 is connected to the b contact when the emergency generator is in normal operation, and switches to the a contact in conjunction with the third relay coil 470, which is excited when the emergency generator is overloaded, thereby interlocking with the molded circuit breaker 510. The molded circuit breaker contact point 550 opens to block the emergency power (ATS 220V) from being supplied to the load side (MC).

The embodiments described in this specification and the accompanying drawings merely illustratively illustrate some of the technical ideas included in the present invention. Accordingly, the embodiments disclosed in this specification are not intended to limit the technical idea of the present invention, but rather to explain it, and therefore, it is obvious that the scope of the technical idea of the present invention is not limited by these embodiments. All modifications and specific embodiments that can be easily inferred by a person skilled in the art within the scope of the technical idea included in the specification and drawings of the present invention should be construed as being included in the scope of the present invention.

110: noise reduction unit
120: first rectifier
130: First constant voltage unit
210: 1st LED (G)
220: Photocoupler light emitting unit
230: Photocoupler light receiving unit
240: Switching voltage application unit
250: first switching unit
260: second relay coil
311, 321, ..., 3N1: 1st to Nth firefighting power sources
313, 323, ..., 3N3: 1st to Nth fire detection switches
315, 325, ..., 3N5: 1st to Nth reverse charge prevention units
317, 327, ..., 3N7: 1st to Nth fire occurrence display units
410: Emergency generator
420: Overload detection unit
430: second rectifier
440: Second constant voltage unit
450: Reverse current prevention unit
460: Overload detection display unit
470: Third relay coil
510: molded circuit breaker
520, 530, 540: first to third relay switches
550: molded circuit breaker contact

Claims (7)

In a distribution board that supplies emergency power to loads including electrical equipment arranged in a plurality of buildings,
An emergency overload wiring blocking main circuit configured to supply emergency power to the load through an automatic transfer switch in the event of a fire or power outage, and to cut off the emergency power when the load reaches an overload state in the event of a fire or power outage;
an emergency overload detection circuit configured to display a malfunction for the building when a fire occurs in one or more of the plurality of buildings;
A constant power priority operation control circuit that excites the first relay coil using constant power; and
When a fire occurs in one or more of the plurality of buildings, a fire monitoring composite circuit that excites the second relay coil using the fire power of the building.
A distribution board with a selective fire indication function by synthesizing the potential of multiple direct current power sources including.
The method of claim 1, wherein the emergency overload wiring blocking main circuit is,
A circuit breaker disposed between the hot line connected to the automatic transfer switch and the third relay switch below;
a third relay switch connected between the other end of the molded circuit breaker and one end of a first relay switch, the first relay switch being interlocked with the first relay coil; and
A second relay switch connected in parallel with the first relay switch and the other end connected to a ground line connected to the automatic transfer switch - The second relay switch is linked to the second relay coil -
A distribution board with a selective fire indication function by synthesizing the potential of multiple direct current power sources including.
The method of claim 2, wherein the emergency overload detection circuit,
an overload detection unit that outputs an overload detection signal when the load power consumed by the load exceeds a predetermined range;
a second rectifier that rectifies the emergency power output from the emergency generator when the overload detection signal is output;
a second constant voltage unit converting the rectified voltage output from the second rectifier into a predetermined constant voltage;
an overload detection display unit that emits light according to the output of the second constant voltage unit;
a third relay coil excited according to the output of the second constant voltage unit; and
A reverse current prevention unit that prevents reverse current from the third relay coil to the second constant voltage unit.
A distribution board with a selective fire indication function by synthesizing the potential of multiple direct current power sources including.
The method of claim 2, wherein the fire monitoring composite circuit,
Comprising first to Nth (where N is 2 or more) fire detection units disposed in each of the plurality of buildings,
Each of the first to Nth fire detection units,
A fire detection switch connected in series to the fire power supply;
a reverse charge prevention unit disposed between the fire-fighting power source and the first relay coil; and
A fire occurrence display unit disposed between the fire monitoring switch and the other end of the first relay coil and emitting light in the event of a fire in the building.
A distribution board with a selective fire indication function by synthesizing the potential of multiple direct current power sources including.
The method of claim 2, wherein the constant power priority operation control circuit,
A first LED that emits light when constant power is applied;
A photocoupler light emitting unit connected in parallel with the constant power source and emitting light when the constant power source is applied;
A photocoupler light receiving unit disposed between the power voltage terminal and the ground terminal and linked to the operation of the photocoupler light emitting unit;
a switching voltage application unit disposed between the photocoupler light receiving unit and a ground terminal and maintaining a switching voltage at a predetermined level when the photocoupler light receiving unit is turned on;
a first switching unit disposed between the power voltage terminal and the ground terminal and switching by receiving the switching voltage output from the switching voltage application unit to a control terminal; and
A second relay coil is disposed between the power voltage terminal and the first switching unit and is excited when the first switching unit is turned on.
A distribution board with a selective fire indication function by synthesizing the potential of multiple direct current power sources including.
In claim 2,
The third relay switch is connected to the molded circuit breaker and contact point B,
The first relay switch is connected to the third relay switch through a contact point,
A distribution board with a selective fire display function by direct current multi-power source potential synthesis, wherein the second relay switch is connected to the third relay switch through a b contact.
In a distribution board that supplies emergency power to loads including electrical equipment arranged in a plurality of buildings,
It is configured to supply emergency power to the load through an automatic transfer switch in the event of a fire or power outage, and is configured to cut off the emergency power when the load reaches an overload state in the event of a fire or power outage,
A distribution board with a selective fire display function by direct current multi-power source potential synthesis, characterized in that when a fire occurs in one or more of the plurality of buildings, a fire is displayed for the relevant building.