KR102305175B1 - Fire fighting power controller device installed in a community building - Google Patents

Abstract

The present invention relates to a firefighting power controller device installed in a community building, which comprises: a firefighting equipment unit which has a number of firefighting facilities including a detector for detecting heat or smoke, a receiver specifying the location of ignition, a transmitter, and an automatic fire detection system having an alarm device for generating an alarm; a power supply unit which supplies commercial power to the firefighting equipment unit; and an emergency power supply unit which supplies emergency power so that a firefighting equipment unit side can be operated through automatic switching by an automatic switching switch when the supply of commercial power is cut off from the power supply unit by an external factor. According to the present invention, it is possible to stably supply and maintain commercial power or emergency power to the firefighting equipment unit in a firefighting power system constructed in a community building.

Description

A firefighting power controller installed in a common building {FIRE FIGHTING POWER CONTROLLER DEVICE INSTALLED IN A COMMUNITY BUILDING}

The present invention relates to a firefighting power controller device installed in a common building, and more particularly, to stably supply and maintain commercial power or emergency power to the firefighting equipment side in a firefighting power system constructed in a common building, and through this It relates to a firefighting power controller installed in a common building that enables stable operation of the firefighting equipment department.

In general, a fire-fighting system is built to detect and extinguish a fire in a building, officetel, multi-family, apartment, etc., which are collective buildings where one or more people or groups work or live together.

In response to the structural design of a common building having various structural types, a detector, an alarm device, an automatic fire detection system, sprinkler, and a fire shutter are installed in this firefighting system system, and the control unit controls it according to the fire detection signal from the detector. It is installed to give a command to operate an alarm device, sprinkler, fire shutter, etc.

In addition, for the operation of the firefighting equipment, such as generating a signal from a detector, processing a control command signal from the control unit, or operating a sprinkler or fire shutter, the supply of firefighting power is essential under any conditions and conditions.

Accordingly, an emergency power supply for firefighting is included in the firefighting power system so that power can be supplied to various firefighting facilities even in the event of a power outage or fire, and emergency power including self-generation facilities so that the firefighting facilities can be operated at all times even in an emergency. It is stipulated by law to secure the

On the other hand, fire-fighting objects such as common buildings having the above-mentioned various structural forms have recently been enlarged in size and have become high-rise, and accordingly, the required fire power is also increasing in capacity. management is very important.

In addition, when a fire occurs compared to usual, most alarm devices and fire extinguishing facilities are controlled and operated. At this time, the load current is generated to the maximum, and various firefighting facilities are properly operated due to the voltage drop of the reserve power including the fire fighting power controller. There may be cases where it does not work.

As described above, when a problem occurs in the supply and control of firefighting power such as emergency power in case of a power outage or fire, serious damage to life and property may be induced, and improvement is required.

In addition, this problem has a problem in that the load such as voltage drop increases even when commercial power is supplied as well as emergency power in the firefighting power system, which makes it difficult for normal operation of fire extinguishing facilities and accurate fire detection. , the load can be further increased in case of an emergency.

Republic of Korea Patent Publication No. 10-2035764 Republic of Korea Patent Publication No. 10-1825685 Republic of Korea Patent Publication No. 10-1796308

The present invention has been devised in consideration of and solving the problems of the prior art, and enables to stably supply and maintain commercial power or emergency power to the firefighting equipment part in a firefighting power system built in a common building, and through this, the firefighting equipment department An object of the present invention is to provide a firefighting power controller installed in a common building that enables stable operation.

The present invention is a firefighting power controller device installed in a common building to automatically extinguish the fire in the initial stage when a fire occurs in the emergency power supply unit installed to supply emergency power to the load side of the firefighting equipment unit in the firefighting power system Its purpose is to provide

The present invention is a firefighting power controller installed in a common building to have the strength to withstand external forces such as earthquakes in the emergency power supply unit installed to supply emergency power to the load side of the firefighting equipment unit in the firefighting power system The purpose is to provide a device.

A firefighting power controller device installed in a common building according to the present invention for achieving the above object is automatic fire detection having a detector for detecting heat or smoke, a receiver specifying a place of ignition, a transmitter, and an alarm device for generating an alarm Fire-fighting equipment unit including a number of fire-fighting facilities, including equipment; a power supply unit for supplying commercial power to the firefighting equipment unit; Including, but the emergency power supply; In the fire-fighting power controller device installed in a common building where at least one group is installed and used among self-generation facilities, storage battery facilities, electrical storage devices, and emergency power reception facilities, the unit is connected to the output terminal of the power supply unit to supply commercial power a commercial power monitoring unit for monitoring the supply state of the trunk line and the terminal to determine whether the voltage drops or not, and to compensate the voltage drop when the voltage drop is determined; It further includes; an emergency power monitoring unit connected to the output terminal of the emergency power supply unit to monitor the supply state of the trunk line and the terminal when emergency power is supplied, to determine whether the voltage drops or not, and to compensate for the voltage drop when determining the voltage drop. Each of the power supply unit and the emergency power supply unit is provided in two or more and dispersedly arranged on the fire fighting power system, but the area for each section is determined for the fire fighting equipment unit so that the fire fighting power is evenly distributed and distributed for each section. Characterized in that.

Here, the commercial power monitoring unit and the emergency power monitoring unit may each include: a trunk voltage measuring unit for measuring a commercial power supply or an emergency power side trunk voltage supplied to the firefighting equipment; an end voltage measuring unit for measuring the end voltage of commercial power or emergency power supplied to the firefighting equipment unit; a load capacity calculating unit for calculating a load capacity for each section between the trunk line and the end based on the rated voltage through the trunk voltage and the end voltage measured by the trunk voltage measuring unit and the end voltage measuring unit; a voltage drop calculation unit for calculating a voltage drop between the trunk line and the terminal side based on the trunk voltage and the terminal voltage measured by the trunk voltage measuring unit and the terminal voltage measuring unit, the load capacity calculated by the load capacity calculating unit, and the rated voltage; a voltage drop determining unit for finally determining whether to drop the voltage by checking whether the calculated value of the voltage drop on the trunk line or the terminal side in the voltage drop calculation unit is within an allowable lower limit of voltage drop compared to the rated voltage; According to the final decision in the voltage drop determining unit, when the calculated value of the voltage drop on the trunk or terminal side exceeds the allowable lower limit range for voltage drop compared to the rated voltage, the power supply unit through the fire fighting power system using big data or neural network learning data or a fire-fighting power system supply voltage calculation unit for calculating and feeding back an optimal supply voltage to be supplied from the emergency power supply unit.

Here, the commercial power monitoring unit and the emergency power monitoring unit may each include: a trunk voltage measuring unit for measuring the commercial power or emergency power side trunk voltage supplied to the firefighting equipment; an end voltage measuring unit for measuring the end voltage of commercial power or emergency power supplied to the firefighting equipment unit; a load capacity calculating unit for calculating a load capacity for each section between the trunk line and the end based on the rated voltage through the trunk voltage and the end voltage measured by the trunk voltage measuring unit and the end voltage measuring unit; a voltage drop calculator for calculating a voltage drop between the trunk line and the end side based on the trunk voltage and the end voltage measured by the trunk voltage measuring section and the end voltage measuring section, the load capacity calculated by the load capacity calculating section, and the rated voltage; a voltage drop final determination unit for finally determining whether to drop the voltage by checking whether the calculated value of the voltage drop on the trunk line or the terminal side in the voltage drop calculation unit is within an allowable lower limit of voltage drop compared to the rated voltage; If the calculated value of the voltage drop on the main line or the terminal side exceeds the allowable lower limit range for voltage drop compared to the rated voltage according to the final decision in the voltage drop final determination unit, the rated voltage allowed in the firefighting power system is Firefighting power system supply voltage that calculates and feeds back the optimal supply voltage to be supplied from the power supply or emergency power supply through the firefighting power system by calculating and averaging the regression linear equations in the normal supply state and at full load, respectively, based on the maximum supply voltage It may be configured to include; a calculation unit.

Here, the emergency power supply unit uses a storage battery facility or an electric storage device, but the DC voltage output therefrom is boosted to the voltage required by the firefighting equipment unit, and a voltage boost for supplying stable power through constant voltage control Including a converter, wherein the step-up converter, the resonant circuit portion to increase the step-up efficiency while reducing the switching loss due to the step-up between the output end of the storage battery facility or the electrical storage device side and the input end of the fire-fighting equipment that is a load, the The resonance circuit unit includes a first switching circuit in which a first transistor for switching control and a first diode for a rectification function are connected in series, a second switching circuit in which a second transistor for switching control and a second diode for a rectification function are connected in series, It may have a configuration including a resonance capacitor connected and connected between the first switching circuit and the second switching circuit connected in parallel, and a boosting inductor commonly connected and connected to an output terminal of the first and second switching circuits. .

Here, when a fire occurs in the emergency power supply in which at least one group is installed among the self-generation facility, the storage battery facility, the electric storage device, and the emergency power reception facility, a fire initial suppression unit for initially suppressing the fire occurs; The fire initial suppression unit may include: a fire detection sensor for detecting when a fire occurs in the emergency power supply unit; a surveillance camera for state monitoring and monitoring by photographing the emergency power supply; a fire extinguishing system control unit for controlling the start of the automatic fire extinguishing system based on a fire detection signal generated from the fire detection sensor or a control signal input through monitoring by a surveillance camera; and an automatic fire extinguishing device for initially suppressing the fire by starting with a signal generated from the fire extinguishing device control unit, wherein the fire extinguishing device control unit includes a differential pressure electromagnetic valve and is connected to the automatic fire extinguishing device, but supplies a starting current of 20A or more It can be connected as possible to prevent malfunction due to low residual current, and to prevent malfunction due to reverse voltage by connecting a reverse current prevention diode on the wiring line of the starting contact terminal supplying the starting current.

Here, the emergency power supply unit, in which at least one group is installed among the self-generation facility, the storage battery facility, the electric storage device, and the emergency power reception facility, is an earthquake-resistant design unit to have a resistance to vibration generated by an earthquake or other external force; includes; And, the earthquake-resistant design unit, the first base frame disposed on the upper portion of the installation surface on which the emergency power supply unit is installed, and supporting the emergency power supply unit; a second base frame positioned outside the first base frame, spaced apart, and fixedly coupled to an installation surface; a first seismic resistance portion interposed between the installation surface and the first base frame; a second earthquake-resistant part interposed between the first base frame and the second base frame, wherein the first earthquake-resistant part includes: a first fixing bracket fixedly coupled to the installation surface; a first spherical body extending from an upper surface of the first fixing bracket and protruding; a first fastening bracket fixedly coupled to a lower surface of the first base frame; and a first spherical support of a housing structure extending from a lower surface of the first fastening bracket to protrude and support-coupled with a first spherical body embedded therein, wherein the second earthquake-resistant part is fixed to the inner surface of the second base frame a second fixing bracket coupled thereto; a second spherical body extending from a second fixing bracket and protruding toward the first base frame; a second fastening bracket fixedly coupled to an outer surface of the first base frame; The second spherical support of the housing structure extending from the second fastening bracket toward the second base frame to form a protrusion and the second spherical body is internally supported and coupled.

According to the present invention, commercial power or emergency power can be stably supplied and maintained to the fire-fighting equipment side in the fire-fighting power system built in a common building, so that it is possible to achieve usefulness that enables stable operation of the fire-fighting equipment side.

According to the present invention, when a fire occurs in the emergency power supply unit installed to supply emergency power to the load side of the firefighting equipment unit in the firefighting power system, it is possible to achieve the usefulness of automatically suppressing the fire at an early stage.

According to the present invention, when an external force such as an earthquake occurs in the emergency power supply unit installed to supply emergency power to the load side of the firefighting equipment in the firefighting power system, it can have a withstand strength, and It is possible to achieve usefulness that can withstand both horizontal orientations.

1 is a schematic configuration diagram showing a fire fighting power controller device installed in a common building according to an embodiment of the present invention.
2 is a block diagram illustrating a commercial power monitoring unit in a fire fighting power controller device installed in a common building according to an embodiment of the present invention.
3 is a block diagram illustrating an emergency power monitoring unit in a fire fighting power controller device installed in a common building according to an embodiment of the present invention.
4 is a schematic configuration diagram illustrating an emergency power supply unit having a boost converter in a fire fighting power controller device installed in a common building according to an embodiment of the present invention.
5 is a circuit configuration diagram illustrating a step-up converter on the side of the emergency power supply in the fire-fighting power controller device installed in a common building according to an embodiment of the present invention.
6 is a schematic configuration diagram illustrating an emergency power supply unit having an initial fire suppression unit in a fire fighting power controller device installed in a common building according to an embodiment of the present invention.
7 is a schematic configuration diagram illustrating an emergency power supply unit having an earthquake-resistant design unit in a fire fighting power controller device installed in a common building according to an embodiment of the present invention.

Preferred embodiments of the present invention will be described with reference to the accompanying drawings, and the purpose and configuration of the present invention and its features will be better understood through such detailed description.

As shown in Figs. 1 to 7, the firefighting power controller device installed in a common building according to an embodiment of the present invention is a firefighting equipment unit 100, a power supply unit 200, an emergency power supply unit 300, an automatic switching switch ( 400), a commercial power monitoring unit 500, and an emergency power monitoring unit 600 are configured.

The firefighting equipment unit 100 includes an automatic fire detection equipment having a detector for detecting heat or smoke, a receiver specifying a place of ignition, a transmitter, and an alarm device for generating an alarm, as well as sprinkler equipment, indoor fire hydrant equipment, smoke control equipment, and fire prevention equipment. It is a configuration that includes a number of firefighting facilities such as shutters.

The firefighting equipment unit 100 may be classified into firefighting loads, emergency loads, and firefighting loads according to facilities and uses.

The power supply unit 200 is a component for normal operation by supplying commercial power output from the fire fighting power system to the fire fighting equipment unit 100 .

The power supply unit 200 is provided in two or more in the common building and distributed on the fire fighting power system, but the area for each section is determined for the fire fighting equipment 100 so that the fire fighting power is evenly distributed and distributed for each section. can

The emergency power supply unit 300 is an emergency power supply unit 200 to enable the operation of the firefighting equipment 100 side through automatic switching by the automatic switching switch 400 when the supply of commercial power is cut off due to an external factor. It is a component for supplying power.

The emergency power supply unit 300 is connected to the fire fighting power system.

The emergency power supply unit 300 is provided in two or more in the common building in the same form as the power supply unit 200 and distributed over the fire fighting power system, but by defining an area for each section with respect to the fire fighting equipment unit 100, fire power It can be configured to distribute and supply evenly by distributing it to each section.

The emergency power supply unit 300 may be used by installing at least one group among self-generation facilities, storage battery facilities, electrical storage devices, and emergency power reception facilities.

In the emergency power supply unit 300, the self-generation facility has an emergency generator, and a combined capacity generator or a fire-fighting power conservation type generator may be used as a generator for both the firefighting load and the emergency load.

In the emergency power supply unit 300, the storage battery facility may use a fuel cell facility, which is a power generation device that directly converts the chemical energy of hydrogen and oxygen into electric energy through an electrochemical reaction, such as a solid oxide fuel cell (SOFC) or a molten It can be selectively used among carbonated lead fuel cells (MCFCs).

In the emergency power supply unit 300 , the electrical storage device may use an energy storage device (ESS), and may have a configuration including a power charging/discharging unit, a battery, a battery sensing unit, and a controller.

The controller includes a power supply device, a control algorithm arithmetic device, a communication device, a frequency measuring device, a driving console, and a data storage device.

It will be said that the emergency power supply unit 300 may be composed of a complex facility if necessary.

Here, the emergency power supply unit 300 may use a storage battery facility or an electric storage device as shown in FIG. It includes a step-up converter 310 for step-up processing and supplying stable power through constant voltage control.

As shown in FIG. 5 , the step-up converter 310 increases the step-up efficiency while reducing the switching loss due to the step-up between the output end of the storage battery facility or the electrical storage device and the input end of the fire-fighting equipment 100 that is the load. and a configuration for forming a resonance circuit unit.

The resonance circuit unit includes a first switching circuit in which a first transistor Q1 for switching control and a first diode D1 for a rectification function are connected in series, a second transistor Q2 for switching control and a second transistor Q2 for a rectification function A second switching circuit in which two diodes D2 are connected in series, a resonance capacitor C1 connected between the first and second switching circuits connected in parallel, and the first switching circuit and the second switching circuit and a voltage boosting inductor (L1) commonly connected and connected to the output terminal.

In this case, the step-up converter 310 may be configured to include a power converter to convert the boosted DC into AC power and supply it.

In addition, the emergency power supply unit 300 uses a storage battery facility or an electric storage device, but may include a power converter that converts direct current output therefrom into alternating current required by the firefighting equipment unit 100 .

Furthermore, when a fire occurs in the emergency power supply in which at least one group is installed among the self-generation facility, the storage battery facility, the electrical storage device, and the emergency power receiving facility, the fire initial suppression unit 320 for initially suppressing it. can be

As shown in FIG. 6, the fire initial suppression unit 320 includes a fire detection sensor 321 for detecting when a fire occurs in the emergency power supply unit 300, and the emergency power supply unit 300. A monitoring camera 322 for state monitoring and monitoring, and a fire detection signal generated from the fire detection sensor 321 or a control signal input through monitoring by the monitoring camera 322, the automatic fire extinguishing device is started It includes a fire extinguishing system control unit 323 that controls the fire extinguishing system, and an automatic fire extinguishing system 324 for initially suppressing the fire by starting with a signal generated by the fire extinguishing system control unit 323 .

At this time, the fire extinguishing device control unit 323 is provided with a differential pressure electromagnetic valve and is connected to the automatic fire extinguishing device 324, but by connecting a starting current of 20A or more so as to prevent malfunction due to a low residual current, the starting current It is preferable to connect a reverse current prevention diode on the connection line of the starting contact terminal supplying the , so as to prevent a malfunction due to the reverse current voltage.

As the fire detection sensor 321, a heat sensor, a smoke sensor, a gas sensor, etc. may be used.

The automatic fire extinguishing device 324 may be an automatic powder fire extinguisher, sprinkler, or the like.

The fire initial suppression unit 320 having such a configuration may also be provided in the power supply unit 200 for supplying commercial power.

When the commercial power supplied to the firefighting equipment 100 through the firefighting power system is cut off by an external force such as a power outage, the automatic switching switch 400 recognizes this immediately and automatically switches to the emergency power supply unit 300 by switching. It is a component that causes emergency power to be supplied to the fire-fighting equipment 100 side by performing .

The automatic switching switch 400 is preferably provided to enable time limit setting during power outage and power recovery, to perform priority switching of commercial power during power recovery after power failure, and to perform an alarm function by detecting frequency and overcurrent.

The commercial power monitoring unit 500 is connected to the output terminal of the power supply unit 200 and is a component for monitoring the supply state of commercial power. Commercial power is supplied from the trunk and the end of the load side to which the commercial power is supplied to the firefighting equipment unit. It is a component for monitoring the state to determine whether or not to drop the voltage, and to provide feedback and compensation when the voltage drop is determined.

To this end, the commercial power monitoring unit 500 includes, as shown in FIG. 2 , a trunk voltage measuring unit 510 for measuring the commercial power supply-side trunk voltage supplied to the firefighting equipment 100; an end voltage measuring unit 520 for measuring the end voltage of the commercial power supplied to the firefighting equipment unit 100; A load capacity calculating unit 530 for calculating the load capacity for each section between the trunk line and the end based on the rated voltage through the trunk voltage and the end voltage measured by the trunk voltage measuring unit 510 and the end voltage measuring unit 520 . Wow; The trunk and terminal voltage drops are calculated based on the trunk voltage and the terminal voltage measured by the trunk voltage measuring unit 510 and the terminal voltage measuring unit 520, the load capacity calculated by the load capacity calculating unit, and the rated voltage. and a voltage drop calculator 540; a voltage drop determining unit 550 for finally determining whether to drop the voltage by checking whether the calculated value of the voltage drop on the trunk line or the terminal side in the voltage drop calculation unit 540 is within an allowable lower limit of voltage drop compared to the rated voltage; According to the final decision in the voltage drop determining unit 550, if the calculated value of the voltage drop on the trunk or terminal side exceeds the allowable lower limit range for voltage drop compared to the rated voltage, it is through the fire fighting power system using big data or neural network learning data. It may be configured to include a fire-fighting power system supply voltage calculation unit 560 that calculates and feeds back an optimal supply voltage to be supplied from the power supply unit 200 .

The emergency power monitoring unit 600 is connected to the output terminal of the emergency power supply unit 300 and is a component for monitoring the supply state when emergency power is supplied. It is a component to monitor the supply state in the , to determine whether or not to drop the voltage, and to provide feedback and compensation when it is determined as a voltage drop.

To this end, the emergency power monitoring unit 600 includes, as shown in FIG. 3 , a trunk voltage measuring unit 610 for measuring the emergency power side trunk voltage supplied to the firefighting equipment 100; a terminal voltage measuring unit 620 for measuring the terminal voltage on the side of the emergency power supplied to the firefighting equipment 100; A load capacity calculation unit 630 for calculating the load capacity for each section between the trunk line and the end based on the rated voltage through the trunk voltage and the end voltage measured by the trunk voltage measuring unit 610 and the end voltage measuring unit 620 . Wow; The trunk and terminal voltage drops are calculated based on the trunk voltage and the terminal voltage measured by the trunk voltage measuring unit 610 and the terminal voltage measuring unit 620, the load capacity calculated by the load capacity calculating unit, and the rated voltage. a voltage drop calculation unit 640 and; a voltage drop determination unit 650 for finally determining whether to drop the voltage by checking whether the calculated value of the voltage drop on the trunk line or the terminal side in the voltage drop calculation unit 640 is within the allowable lower limit range for voltage drop compared to the rated voltage; According to the final decision in the voltage drop determining unit 650, when the calculated value of the voltage drop on the trunk or terminal side exceeds the allowable lower limit range for voltage drop compared to the rated voltage, it is through the fire fighting power system using big data or neural network learning data. The emergency power supply unit 300 may have a configuration including a fire-fighting power system supply voltage calculating unit 660 that calculates and feeds back an optimal supply voltage to be supplied.

Here, the fire-fighting power system supply voltage calculation unit 560, 660 calculates the voltage drop on the trunk line or the terminal side according to the final determination in the voltage drop final determination unit 550 and 560, the voltage drop compared to the rated voltage. If the permissible lower limit is exceeded, the fire power system is calculated by using the linear regression analysis technique to obtain the regression linear equations in the normal supply state and at full load, respectively, based on the maximum supply voltage of the rated voltage allowed in the fire fighting power system, and then averaging them. It can also be configured in such a way that the optimal supply voltage to be supplied from the power supply unit 200 or the emergency power supply unit 300 is calculated and fed back through.

Here, the allowable lower limit of voltage drop compared to the rated voltage is preferably within 20%.

Here, a voltmeter or the like may be used to measure the trunk voltage or the terminal voltage.

On the other hand, the emergency power supply unit 300, in which at least one group is installed among the self-generation facility, the storage battery facility, the electrical storage device, and the emergency power reception facility, is a seismic design unit for having a resistance to vibration generated by an earthquake or other external force. may include

As shown in FIG. 7 , the earthquake-resistant design unit includes a first base frame 301 disposed on the installation surface on which the emergency power supply unit 300 is installed and supporting the emergency power supply unit, and the first base frame 301 . ) located outside the second base frame 302 spaced apart and fixedly coupled to the installation surface, and interposed between the installation surface and the first base frame 301 to have a load-bearing force mainly in the vertical direction It includes a first seismic-resistant part 303 and a second seismic-resistant part 304 interposed between the first base frame 301 and the second base frame 302 to mainly have a bearing capacity in the left and right horizontal directions.

The first seismic portion 303 includes a plate-shaped first fixing bracket 303a fixedly coupled to the installation surface, and a first spherical body 303b extending from the upper surface of the first fixing bracket and formed to protrude; A first spherical housing structure in which a plate-shaped first fastening bracket 303c is fixedly coupled to the lower surface of the first base frame and extends from the lower surface of the first fastening bracket to form a protrusion and the first spherical body is internally supported and coupled and a support 303d.

The second earthquake-resistant part 304 includes a plate-shaped second fixing bracket 304a fixedly coupled to the inner surface of the second base frame 302 and extending from the second fixing bracket toward the first base frame and protruding. A second spherical body (304b) formed, a plate-shaped second fastening bracket (304c) fixedly coupled to the outer surface of the first base frame, and extending from the second fastening bracket toward the second base frame to form a protrusion and a second spherical support 304d of a housing structure to which a second spherical body is embedded and supported.

That is, the first seismic-resistant part 303 and the second seismic-resistant part 304 are buffered by movement in the first spherical body 303b and the second spherical body 304b when an external force such as an earthquake acts, respectively. Through the action, by supporting the emergency power supply unit 300 in both the vertical direction and the horizontal direction, it exhibits a function of maintaining the installation state.

The seismic design unit having such a configuration may be applied to the power supply unit 200 side for supplying commercial power, and may be applied to a switchboard or the like.

On the other hand, the plurality of components described in the present invention can be selectively configured or installed in a complex manner as needed.

The embodiments described above are merely illustrative of preferred embodiments of the present invention and are not limited to these embodiments, and various modifications and variations by those skilled in the art within the spirit and claims of the present invention It will be said that this can be done, and it will be said that it falls within the scope of the technical rights of the present invention.

100: firefighting equipment unit 200: power supply unit
300: emergency power supply 310: step-up converter
320: fire initial suppression unit 400: automatic switching switch
500: commercial power monitoring unit 600: emergency power monitoring unit

Claims (6)

delete a firefighting equipment section including a plurality of firefighting facilities including a detector for detecting heat or smoke, a receiver for specifying a place of ignition, a transmitter, and an automatic fire detection facility having an alarm device for generating an alarm; a power supply unit for supplying commercial power to the firefighting equipment unit; Including, but the emergency power supply; In the fire-fighting power controller device installed in a common building where at least one group is installed and used among self-generation facilities, storage battery facilities, electrical storage devices, and emergency power reception facilities,
a commercial power monitoring unit connected to the output terminal of the power supply unit to monitor a supply state of a trunk line and an end to which commercial power is supplied to determine whether a voltage drop occurs and to compensate for the voltage drop when determined as a voltage drop;
an emergency power monitoring unit connected to the output terminal of the emergency power supply unit to monitor the supply state of the trunk line and the terminal when emergency power is supplied to determine whether the voltage drops or not, and to compensate for the voltage drop when determining the voltage drop; further comprising,
The power supply unit and the emergency power supply unit are each provided in two or more and dispersedly arranged on the fire fighting power system, but the area for each section is determined for the fire fighting equipment unit so that the fire fighting power is evenly distributed and distributed for each section,
The commercial power monitoring unit and the emergency power monitoring unit, respectively,
a trunk voltage measurement unit for measuring the trunk voltage of commercial power or emergency power supplied to the firefighting equipment; an end voltage measuring unit for measuring the end voltage of commercial power or emergency power supplied to the firefighting equipment unit; a load capacity calculating unit for calculating a load capacity for each section between the trunk line and the end based on the rated voltage through the trunk voltage and the end voltage measured by the trunk voltage measuring unit and the end voltage measuring unit; a voltage drop calculation unit for calculating a voltage drop between the trunk line and the terminal side based on the trunk voltage and the terminal voltage measured by the trunk voltage measuring unit and the terminal voltage measuring unit, the load capacity calculated by the load capacity calculating unit, and the rated voltage; a voltage drop determining unit for finally determining whether to drop the voltage by checking whether the calculated value of the voltage drop on the trunk line or the terminal side in the voltage drop calculation unit is within an allowable lower limit of voltage drop compared to the rated voltage; According to the final decision in the voltage drop determining unit, when the calculated value of the voltage drop on the trunk or terminal side exceeds the allowable lower limit range for voltage drop compared to the rated voltage, the power supply unit through the fire fighting power system using big data or neural network learning data or a fire-fighting power system supply voltage calculation unit for calculating and feeding back an optimal supply voltage to be supplied from the emergency power supply unit; Firefighting power controller device installed in a common building, characterized in that it comprises a. a firefighting equipment section including a plurality of firefighting facilities including a detector for detecting heat or smoke, a receiver for specifying a place of ignition, a transmitter, and an automatic fire detection facility having an alarm device for generating an alarm; a power supply unit for supplying commercial power to the firefighting equipment unit; Including, but the emergency power supply; In the fire-fighting power controller device installed in a common building where at least one group is installed and used among self-generation facilities, storage battery facilities, electrical storage devices, and emergency power reception facilities,
a commercial power monitoring unit connected to the output terminal of the power supply unit to monitor a supply state of a trunk line and an end to which commercial power is supplied to determine whether a voltage drop occurs and to compensate for the voltage drop when determined as a voltage drop;
an emergency power monitoring unit connected to the output terminal of the emergency power supply unit to monitor the supply state of the trunk line and the terminal when emergency power is supplied to determine whether the voltage drops or not, and to compensate for the voltage drop when determining the voltage drop; further comprising,
The power supply unit and the emergency power supply unit are each provided in two or more and dispersedly arranged on the fire fighting power system, but the area for each section is determined for the fire fighting equipment unit so that the fire fighting power is evenly distributed and distributed for each section,
The commercial power monitoring unit and the emergency power monitoring unit, respectively,
a trunk voltage measuring unit for measuring the trunk voltage of commercial power or emergency power supplied to the firefighting equipment; an end voltage measuring unit for measuring the end voltage of commercial power or emergency power supplied to the firefighting equipment unit; a load capacity calculating unit for calculating a load capacity for each section between the trunk line and the end based on the rated voltage through the trunk voltage and the end voltage measured by the trunk voltage measuring unit and the end voltage measuring unit; a voltage drop calculator for calculating a voltage drop between the trunk line and the end side based on the trunk voltage and the end voltage measured by the trunk voltage measuring section and the end voltage measuring section, the load capacity calculated by the load capacity calculating section, and the rated voltage; a voltage drop final determination unit for finally determining whether to drop the voltage by checking whether the calculated value of the voltage drop on the trunk line or the terminal side in the voltage drop calculation unit is within an allowable lower limit of voltage drop compared to the rated voltage; If the calculated value of the voltage drop on the main line or the terminal side exceeds the allowable lower limit range for voltage drop compared to the rated voltage according to the final decision in the voltage drop final determination unit, the rated voltage allowed in the firefighting power system is Firefighting power system supply voltage that calculates and feeds back the optimal supply voltage to be supplied from the power supply or emergency power supply through the firefighting power system by calculating and averaging the regression linear equations in the normal supply state and at full load, respectively, based on the maximum supply voltage output unit; Firefighting power controller device installed in a common building, characterized in that it comprises a. 4. The method of claim 2 or 3,
The emergency power supply unit,
A storage battery facility or electrical storage device is used, but the DC voltage output therefrom is boosted to the voltage required by the firefighting equipment department and includes a step-up converter for supplying stable power through constant voltage control,
The step-up converter is
A resonance circuit is formed between the output terminal of the storage battery facility or the electrical storage device and the input terminal of the fire-fighting equipment, which is a load, to increase the boosting efficiency while reducing the switching loss due to the boosting,
The resonance circuit unit,
A first switching circuit in which a first transistor for switching control and a first diode for a rectification function are connected in series;
A second switching circuit in which a second transistor for switching control and a second diode for a rectification function are connected in series;
A capacitor for resonance connected between the first switching circuit and the second switching circuit connected in parallel;
and a boosting inductor commonly connected to an output terminal of the first and second switching circuits and connected to the first switching circuit and the second switching circuit. 4. The method of claim 2 or 3,
a fire initial suppression unit for initially suppressing a fire when a fire occurs in the emergency power supply unit in which at least one group is installed among the self-generation facility, the storage battery facility, the electric storage device, and the emergency power reception facility; includes,
The fire extinguishing unit,
a fire detection sensor for detecting a fire in the emergency power supply unit;
a surveillance camera for state monitoring and monitoring by photographing the emergency power supply;
a fire extinguishing system control unit for controlling the start of the automatic fire extinguishing system based on a fire detection signal generated from the fire detection sensor or a control signal input through monitoring by a surveillance camera;
an automatic fire extinguishing device for initially suppressing a fire by starting with a signal generated by the fire extinguishing device control unit; including,
The fire extinguishing system control unit is provided with a differential pressure solenoid valve and is connected to the automatic fire extinguishing apparatus, but by connecting the starting current to be supplied at 20A or more to prevent malfunction due to low residual current, and wiring of the starting contact terminal supplying the starting current A firefighting power controller installed in a common building, characterized in that it is configured to prevent a malfunction due to a reverse voltage by connecting a reverse flow prevention diode on the line. 4. The method of claim 2 or 3,
The emergency power supply unit in which at least one group is installed among the self-generation facility, the storage battery facility, the electrical storage device, and the emergency power reception facility includes: an earthquake-resistant design unit to have a resistance to vibration generated by an earthquake or other external force; includes,
The seismic design unit,
a first base frame disposed on the installation surface on which the emergency power supply unit is installed and supporting the emergency power supply unit;
a second base frame positioned outside the first base frame, spaced apart, and fixedly coupled to an installation surface;
a first seismic resistance portion interposed between the installation surface and the first base frame;
a second seismic resistance portion interposed between the first base frame and the second base frame; including,
The first earthquake-resistant part,
a first fixing bracket fixedly coupled to the installation surface;
a first spherical body extending from an upper surface of the first fixing bracket and protruding;
a first fastening bracket fixedly coupled to a lower surface of the first base frame;
a first spherical support of a housing structure extending from a lower surface of the first fastening bracket to form a protrusion and a first spherical body to be internally supported and coupled; including,
The second earthquake-resistant part,
a second fixing bracket fixedly coupled to the inner surface of the second base frame;
a second spherical body extending from a second fixing bracket and protruding toward the first base frame;
a second fastening bracket fixedly coupled to an outer surface of the first base frame;
a second spherical support of a housing structure extending from a second fastening bracket toward the second base frame to protrude and a second spherical body is embedded therein; Firefighting power controller device installed in a common building, characterized in that it comprises a.

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