KR101796841B1 - Building monitoring system and the operating method therefor - Google Patents

Abstract

The present invention relates to a building control system and a driving method thereof, and it provides an interface for accommodating standardized various sensors or guidance meters installed in a building to be controlled, facilitates expansion and modification of various sensors and guidance meters, And the information is transmitted to the integrated control server at the time of occurrence of an abnormal condition and abnormal release, thereby efficiently reducing the processing data and the load of the integrated control server, And more particularly, to a building control system that provides an abnormal state of a building and an abnormal release state through an emergency communication network and a driving method thereof.
To this end, according to the present invention, various standardized sensors or guidance meters installed in a building to be controlled are connected and it is judged whether or not there is an abnormality from the data provided from the various sensors or guidance meters. When abnormality occurs, A detection receiver 100 for transmitting the information to the server 200 and an integrated control server 300 for transmitting information on the abnormal state occurrence and abnormal release state provided from the detection receiver 100 through the emergency communication network 300 200), and a method of driving the same.

Description

[0001] The present invention relates to a building monitoring system and a driving method thereof,

The present invention relates to a building control system and a driving method thereof, and it provides an interface for accommodating standardized various sensors or guidance meters installed in a building to be controlled, facilitates expansion and modification of various sensors and guidance meters, And the information is transmitted to the integrated control server at the time of occurrence of an abnormal condition and abnormal release, thereby efficiently reducing the processing data and the load of the integrated control server, And more particularly, to a building control system that provides an abnormal state of a building and an abnormal release state through an emergency communication network and a driving method thereof.

As a background of the building control system and its driving method of the present invention, a database construction and user interface processing for building information monitoring in a remote building control system of Korean Patent Laid-Open Publication No. 10-2012-0070653A shown in FIG. Device and method thereof. This technology relates to database construction and user interface processing technology for building information monitoring in a remote building control system. It monitors and analyzes individual buildings and establishes remote It provides a consistent view of building management in the building management system, provides monitoring interfaces from various viewpoints, and builds high performance data and user interface processing to support it.

As another background of the present invention, there is a building monitoring system using a smart device of Korean Patent Laid-Open Publication No. 10-2015-0107916A shown in FIG. 2 and a monitoring method therefor. According to an aspect of the present invention, there is provided a method for controlling an emergency situation in a building, the method comprising the steps of: detecting a predetermined emergency condition; generating a warning signal according to the emergency condition and transmitting the alarm signal together with the unique identification information; A display panel for displaying a normal situation and an emergency situation for each of the plurality of areas; And controlling the display panel to display the normal state and the emergency state for each area in different colors according to an alarm signal and unique identification information (ID) received from the detection sensor, A control unit for controlling the display panel to display the first color indicating the emergency situation and the second color indicating the normal situation for the area where the alarm signal is not generated; Wherein a dedicated application program for displaying in association with the normal situation and the emergency situation for each of the plurality of areas displayed on the display panel is installed and executed, A smart device for receiving and displaying an emergency situation; And a communication network for processing data communication between the control device and the smart device.

As another background of the present invention, there is an apparatus and a method for remotely monitoring the building state of Korean Patent Laid-Open Publication No. 10-2015-0010847A shown in FIG. 3. This technique includes a receiving unit for receiving state data of the building from a plurality of sensors for measuring the state of the building, a state database for storing the state data, a reference database for storing a criterion for determining abnormality of the state data, A safety determination unit that extracts abnormal information that is determined to be in an abnormal range among the status data, and an abnormal database that stores the abnormal information.

KR 10-2012-0070653 A KR 10-2015-0107916 A KR 10-2015-0010847 A KR 10-1398819 B1 KR 10-1281702 B1 KR 10-2012-0098606 A KR 10-1336571 B1

The object of the present invention is to provide a building management system and a method of driving the same that provide an interface for accommodating standardized various sensors or guidance meters installed in a building to be controlled and facilitate expansion and change of various sensors and guidance meters .

Further, the present invention is configured to determine the presence or absence of an abnormality from data provided from various sensors or guidance meters installed in a building to be controlled, and to transmit the information to the integrated control server at the time of occurrence of an abnormal condition and abnormality release, A building control system and method for efficiently reducing processing data and load are provided.

Another object of the present invention is to provide a building control system and a method of driving the same that provide an abnormal state occurrence and an abnormal release state of a building to be controlled through an emergency contact network.

In the present invention, various standardized sensors or guidance meters installed in a building to be controlled are connected, and it is determined whether there is an abnormality from data provided from the various sensors or guidance meters. 200 for transmitting the information of the abnormal state and the abnormal state provided from the sensing receiver 100 to the integrated control server 200 through the emergency communication network 300, ; And a driving method thereof, as a solution to the problem.

According to the present invention, it is possible to provide an interface for accommodating standardized various sensors or guidance meters installed in a building to be controlled, facilitate expansion and modification of various sensors and guidance meters, And the information is transmitted to the integrated control server at the time of occurrence of an abnormal condition and abnormal release, thereby efficiently reducing the processing data and the load of the integrated control server, To provide the technical effect through the emergency network.

FIG. 1 is a background diagram of the present invention. FIG. 1 is a block diagram of a database construction and user interface processing apparatus for monitoring building information in a remote building control system
FIG. 2 is another background of the present invention, which is a configuration of a building monitoring system using a smart device and a monitoring method technique thereof
FIG. 3 is another background of the present invention, which is an apparatus and method for remotely monitoring the state of a building
FIG. 4 is a block diagram showing the basic structure of the present invention.
FIG. 5 is a schematic view of a building / facility-specific embodiment
FIG. 6 is a block diagram of a configuration of a sensing receiver 100 in a building control system of the present invention.
7 shows an interface between the sensors and guidance meters and the sensing receiver 100 in the building control system of the present invention.
FIG. 8 is a block diagram illustrating the configuration of the integrated control server 200 in the building control system of the present invention.
9 is a driving method of a building control system according to the present invention,
10 is a driving method of the building control system of the present invention,

The following merely illustrates the principles of the invention. Accordingly, those skilled in the art will be able to devise various apparatuses which, although not explicitly described or shown herein, embody the principles of the invention and are included in the concept and scope of the invention. It is to be understood that all of the conditional terms and embodiments recited herein are expressly intended to be purely for purposes of understanding the concepts of the present invention and are not intended to be limiting to such specifically recited embodiments and conditions . It is also to be understood that the detailed description, as well as the principles, aspects and embodiments of the invention, as well as specific embodiments thereof, are intended to cover structural and functional equivalents thereof.

The above objects, features and advantages will become more apparent from the following detailed description in conjunction with the accompanying drawings. DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENTS Hereinafter, exemplary embodiments of the present invention will be described in detail with reference to the accompanying drawings. Hereinafter, preferred embodiments of the present invention will be described in detail with reference to the accompanying drawings.

FIG. 4 shows an embodiment for a plurality of building controls in a basic configuration of the present invention. In a typical building management system, a server receives and monitors sensor information of a building to be monitored. However, when a large number of buildings are to be controlled, or when a building to be controlled forms a large-sized sensor group, a server that monitors and manages these sensors increases its load, making it difficult to efficiently manage the buildings. In addition, various sensors and guidance meters installed in the target building are standardized according to regulations and regulations, and output signals corresponding to the types are diversified, and an interface that facilitates expansion and modification is required.

The building control system and the driving method thereof according to the present invention include a sensing receiver 100 for receiving and processing signals from various sensors or guidance meters installed in a building to be controlled, 300, and the integrated control server 200 is configured to be a basic configuration.

The sensing receiver 100 monitors signals from various sensors or guidance meters installed in the building to be controlled and transmits the information to the integrated control server 200 when an error occurs. The integrated control server 200 inputs And transmits the abnormality occurrence information and the cancellation information through the emergency communication network including the subscribed building member. The integrated control server 200 may be installed in the control center to manage a plurality of buildings and may be installed between the control center and the sensing receiver 100 separately from the control center as required.

The building control system and the driving method thereof according to the present invention provide the following technical features.

First, the sensing receiver 100 of the present invention provides an interface for accommodating standardized various sensors or guidance meters installed in a building to be controlled.

Second, the sensing receiver 100 of the present invention provides a configuration that facilitates expansion and modification of various sensors and guidance meters.

Thirdly, the detection receiver 100 of the present invention determines whether there is an abnormality from data provided from various sensors or guidance meters, and transmits the information to the integrated control server 200 at the time of occurrence of an abnormal condition and abnormal release Thereby effectively reducing the processing data and the load of the integrated control server 200.

Fourth, the integrated control server 200 of the present invention transmits an abnormal state occurrence and an abnormal release state of the control target building through the emergency communication network 300.

FIG. 5 shows an embodiment of a building / facility of the present invention. The building control system of the present invention comprises: Various standardized sensors or guidance meters installed in the building to be controlled are connected and the abnormality is determined from the data provided from the various sensors or guidance meters, And an integrated control server (200) for transmitting information on an abnormal state occurrence and an abnormal release state provided from the detection receiver (100) through the emergency communication network (300) .

As shown in the figure, various sensors and guidance meters are connected to the sensing receiver 100 of the present invention. Examples of the sensors include a fire detection sensor, a crime prevention sensor, a metering guide meter, a water level sensor, a power supply sensor, and the like. The sensor and the guidance meters are equipped with the following electrical output means can do.

For a fire detection sensor, provide 24 [V] as active high signal and 0 [V] as low signal; The security sensor is 5-30 [V] as active high signal, 0 [V] as low signal; The power sensor is analog voltage 0-10 [v]; The water level sensor senses the water level in the water tank of the building and turns it on / off as low and high water level contacts; Gas, electricity, and water metering instructions provide standard serial communication output (eg, RS-485, 488, Ethernet, etc.). Therefore, the sensing receiver 100 of the present invention has an interface that corresponds to the sensor and the guidance meters, and considers scalability and change.

FIG. 6 shows the configuration of the sensing receiver 100 in the building control system of the present invention. The sensing receiver (100) of the present invention comprises:

An MPU 110 (Micro Processor Unit) having a built-in timer for setting a data collection time interval (polling time interval) provided from sensors and instruction meters and performing control of the sensing receiver 100,

An interface for providing data of sensors and instruction meters to the MPU 110, and includes an on / off contact switch or a switch input of a sensor which is turned on / off by a relay contact, and sensors for electrically providing active high and low signals An I / O port 120 for receiving a logic voltage input; At least one A / D converter 130 connected to sensors for providing an analog voltage as an output; And one or more serial ports (140) for input of instructional meters that provide standard serial communication. The serial port 140 may be used as an expansion port connected to a serial port of another sensing receiver and collecting data provided from sensors and guidance meters of other sensing receivers under the control of the MPU 110.

The MPU 110 includes a system information memory 150 for storing information of sensors and instruction meters connected to the I / O port 120, the A / D conversion unit 130, and the serial port 140, A reference value data memory 160 for storing reference values for comparing and judging the abnormality of data provided from sensors and guidance meters of the sensing receiver; A server communication unit 170 for performing communication with the integrated control server 200 under the control of the MPU 110; A building data memory 180 in which building information including an address, an ID, and the like is stored as information of a building to which the sensing receiver 100 is installed; And a field monitor / alarm unit 190 having information on sensors and guidance meters installed in the building to be monitored from the detection receiver 100 and outputting an alarm upon occurrence of an abnormal state and having an initialization / test switch.

FIG. 7 illustrates the interfaces between sensors and guidance meters and the sensing receiver 100 in the building control system of the present invention. As described above, the sensors and the guidance meters installed in the building to be controlled include: a sensor that provides an on / off contact, a sensor that provides an active high and a low signal electrically, a sensor that provides an analog voltage as an output, and guidance meters that provide standard serial communication. The sensor and guiding meters and the sensing receiver 100 are configured to transmit data in an electrically isolated state.

(A) of the figure shows an interface of an on / off contact switch such as a water level sensor or the like and a sensor provided with an output to a relay contact and a corresponding sensing receiver 100. The two output terminals of the sensor are connected to both ends of the LED of the photocoupler. A pull-up resistor Rp is connected between the P-side terminal of the LED and the power supply Vp, and the N-side terminal of the LED is connected to the ground side of the power supply Vp do. A pull-up resistor R o is connected to an internal power source Vo of the sensing receiver 100 isolated from the power source Vp, and a collector of the phototransistor of the photocoupler is connected to an emitter Source) terminal is connected to the ground of the power source Vo. Accordingly, the data of the sensor provided with the output of the contact switch or the relay contact is provided as data having the internal power Vo of the sensing receiver 100 as active high.

(B) of the drawing shows the interface of the sensing receiver 100 corresponding to the sensors electrically providing active high and low signals. The two output terminals of the sensor are opposed to both ends of the LED of the photocoupler and a current limiting series resistance Rs is connected between the P side terminal of the LED and the voltage output terminal of the sensor and the N side terminal of the LED is connected to the ground side of the sensor. A pull-up resistor R o is connected to an internal power source Vo of the sensing receiver 100 isolated from the power source Vp, and a collector of the phototransistor of the photocoupler is connected to an emitter Source) terminal is connected to the ground of the power source Vo. Therefore, the data of the sensor electrically providing the active high signal and the low signal are provided as data having the internal power Vo of the sensing receiver 100 as active high.

(C) of the figure shows the interface of the sensing receiver 100 with the sensors providing the analog voltage as an output. The analog voltage provided to the two output terminals of the sensor is amplified through an insulation amplifier Ai of the sensing receiver 100 and provided as data of the sensing receiver 100 through an A / D converter. An analog multiplexer may be provided at the front end of the isolation amplifier Ai so that multiple analog inputs can be connected.

(D) of the drawing shows the interface of the sensing receiver 100 corresponding to the instruction meters for providing data in serial communication. The guide meters of the serial communication method are connected to a serial port 140 provided in the sensing receiver 100. The serial port 140 is connected to a serial port of another sensing receiver in a master- May be used as an expansion port for collecting data provided from sensors and guidance meters of other sensing receivers under the control of the MPU 110

FIG. 8 shows the configuration of the integrated control server 200 in the building control system of the present invention. The integrated control server 200 of the present invention comprises:

A server CPU 210 for controlling the integrated control server 200; A communication controller 220 connected to the server CPU 210 for communicating with the sensing receiver 100 and storing the received information in the communication buffer 230 and providing the received information to the server CPU 210; An abnormal state building information storage unit 250 for storing information transmitted from the sensing receiver 100 installed in the mobile communication terminal 100; And the building information including the information of the steady state sensors and guidance meters received by the sensing receiver 100 of the building to be monitored and the information of the guidance meters to which the sensing receiver 100 is installed, DB 240; A subscriber mobile information memory (260) for storing information (numbers) of emergency mobiles (300) mobiles for transmitting abnormal state occurrence and abnormal release state of the controlled building by the server CPU (210); A status monitor output unit 270 for externally providing the status of the buildings to be controlled; And a mobile communication unit 280 for transmitting the information on the abnormal state occurrence and abnormal release state of the controlled building to the emergency communication network 300 stored in the subscriber mobile information memory 260 by the server CPU 210 .

FIG. 9 shows a driving method of the sensing receiver 100 as a driving method of the building control system of the present invention. The driving of the sensing receiver 100 according to the present invention is performed mainly on the MPU 110 which performs the control of the sensing receiver 100 and the specific driving method will be described step by step.

S100: the power of the sensing receiver 100 is turned on or reset to start the operation of the sensing receiver 100;

S110: The timer provided in the MPU 110 of the detection receiver 100 is set as a data collection time interval provided from the sensors and the guidance meters,

An initialization step of setting reference values of a reference value data memory 160 for comparing and judging the abnormality of data provided from sensors and guidance meters of the detection receiver to initial values;

- S120: The MPU 110 collects data provided from sensors and guidance meters of the sensing receiver by data collection time intervals set by the timer;

S130: comparing the data collected by the MPU 110 with the reference values of the reference value data memory 160 to determine whether an error has occurred;

If it is determined that the collected data is normal, the MPU 110 repeats step S120.

- S140: If it is determined in step S130 that an abnormality has occurred, the MPU 110 refers to the collected data and the system information memory 150 to generate a sensor and instruction meter information in which the abnormality occurs, To the integrated control server (200) together with the address or ID of the controlled building to be controlled;

- S150: outputting an alarm signal by the MPU 110 through the field monitor / alarm unit 190 of the sensing receiver 100;

S160: determining whether the collected data collected by the MPU 110 from the sensors and the guidance meters of the detection receiver are recovered to normal by data collection time intervals set by the timer;

At this time, if the collected data is still in the abnormal state, the MPU 110 repeats step S150.

- S170: If it is determined that the data collected in step S160 is restored to normal, the MPU 110 blocks the alarm signal through the field monitor / alarm unit 190,

Transmitting the normal recovery code to the integrated control server 200 together with the address or ID of the control target building stored in the building data memory 180, and repeating the process from step S120 again;

.

FIG. 10 shows a driving method of the integrated control server 200 as a driving method of the building control system of the present invention. The operation of the integrated control server 200 of the present invention is performed by the server CPU 210 that controls the integrated control server 200, and a specific driving method will be described step by step.

S200: the operation of the integrated control server 200 is started;

S210: The server CPU 210 of the integrated control server 200 determines whether information transmitted from the sensing receiver 100 and received by the communication controller 220 exists.

At this time, if it is determined that the received information does not exist, the server CPU 210 repeats step S210.

S220: If it is determined that the information received in step S210 is present, the server CPU 210 reads the information received from the communication buffer 230 and displays the address of the building to which the sensing receiver 100 is installed, Retrieving building information from the building information DB 240 including ID and information of steady state sensors and guidance meters received by the sensing receiver 100 of the building to be controlled;

S230: The server CPU 210 compares the information read out from the communication buffer 230 with the information retrieved and collected from the building information DB 240, and if the information is abnormal, the abnormal state building information storage 250 Information stored in the abnormal state building information storage unit 250 in the case of normal state information is deleted and the state of the monitored buildings is stored in the state monitor output unit 270 through the state monitor output unit 270. [ Outputting;

S240: The server CPU 210 transmits an abnormal state of the building to be controlled to the emergency communication network 300 stored in the subscriber mobile information memory 260 via the mobile communication unit 280, ≪ / RTI >

And repeats the process from step S210.

According to the present invention as described above, it is possible to provide an interface for accommodating standardized various sensors or guidance meters installed in a building to be controlled, facilitate expansion and modification of various sensors and guidance meters, And transmits the corresponding information to the integrated control server at the time of occurrence of an abnormal condition and abnormality release, thereby effectively reducing the processing data and the load of the integrated control server, And provides the building control system and the driving method thereof, which provides the occurrence and abnormal release state through the emergency communication network.

While the present invention has been particularly shown and described with reference to exemplary embodiments thereof, it is to be understood that the invention is not limited to the disclosed exemplary embodiments. It goes without saying that various modifications and variations are possible within the scope of equivalence of the scope.

100: Detection receiver 110: MPU
120: I / O port 130: A / D conversion section
140: Serial port 150: System information memory
160: reference value data memory 170: server communication section
180: building data memory 190: field monitor / alarm section
200: Integrated control server 210: Server CPU
220: communication control unit 230: communication buffer
240: building information DB 250: abnormal state building information storage unit
260: Subscriber mobile information memory 270: Status monitor output section
280: mobile communication unit 300: emergency contact network

Claims (15)

In a building control system,
Various standardized sensors or guidance meters installed in a building to be controlled are connected to transmit data in a state that they are electrically isolated and it is judged whether or not there is an abnormality from the data provided from the various sensors or guidance meters, And a detection receiver (100) for transmitting the information to the integrated control server (200) upon abnormal release,
And an integrated control server (200) for transmitting information of an abnormal state occurrence and an abnormal release state provided from the detection receiver (100) to the emergency communication network (300) through the mobile communication unit (280)

The sensing receiver (100)
An MPU 110 (Micro Processor Unit) for controlling the sensing receiver 100,
O port 120, an A / D converter 120, and an I / O port 120. The I / O port 120 is an interface for providing the MPU 110 with data of sensors and instruction meters connected to transmit data in a state electrically insulated from the sensing receiver 100, D conversion unit 130 and a serial port 140,
In the MPU 110,
A timer for setting a data collection time interval (polling time interval) provided from the sensors and the guidance meters;
A system information memory 150 for storing information of sensors and instruction meters connected to the I / O port 120, the A / D conversion unit 130, and the serial port 140;
A reference value data memory (160) for storing reference values for comparing and judging the abnormality of data provided from sensors and guidance meters of the detection receiver;
A server communication unit 170 for performing communication with the integrated control server 200 under the control of the MPU 110;
A building data memory 180 in which building information including an address, an ID, and the like is stored as information of a building to which the sensing receiver 100 is installed;
A field monitor / alarm unit 190 displaying information of sensors and guidance meters installed in the building to be controlled from the sensing receiver 100, outputting an alarm when an abnormal state occurs, and having an initialization / test switch;
And a building control system
delete delete delete delete The interface according to claim 1, wherein the interface for providing the data of the sensor and the guidance meters to the MPU (110)
For sensors provided as contacts on / off,
The two output terminals of the sensor are connected to both ends of the LED of the photocoupler,
A pull-up resistor Rp is connected between the P-side terminal of the LED and the power supply Vp,
The N-side terminal of the LED is connected to the ground side of the power supply Vp,
A pull-up resistor Ro is connected to a collector (drain in the case of a FET) of the phototransistor of the photocoupler, to an internal power supply Vo of the sensing receiver 100 isolated from the power supply Vp,
The emitter (source in the case of FET) terminal is connected to the ground of the power supply Vo,
And to provide the internal power Vo of the sensing receiver 100 as active high data through the I / O port 120. [
The interface according to claim 1, wherein the interface for providing the data of the sensor and the guidance meters to the MPU (110)
For sensors that provide active high and low signals electrically,
The two output terminals of the sensor are opposed to both ends of the LED of the photocoupler and a current limiting series resistor Rs is connected between the P side terminal of the LED and the voltage output terminal of the sensor,
The N-side terminal of the LED is connected to the ground side of the sensor,
A pull-up resistor Ro is connected to a collector (drain in the case of a FET) of the phototransistor of the photocoupler, to a power supply Vp and to an internal power supply Vo of the sensing receiver 100 isolated from the power supply Vp,
The emitter (source in the case of FET) terminal is connected to the ground of the power supply Vo,
And to provide the internal power Vo of the sensing receiver 100 as active high data through the I / O port 120. [
The interface according to claim 1, wherein the interface for providing the data of the sensor and the guidance meters to the MPU (110)
For a sensor that provides an analog voltage as an output,
The analog voltage provided to the two output terminals of the sensor is amplified by an insulation amplifier Ai of the sensing receiver 100 and is supplied as data of the sensing receiver 100 through an A / D converter Building control system featuring
The interface according to claim 1, wherein the interface for providing the data of the sensor and the guidance meters to the MPU (110)
For instructional meters that provide standard serial communication,
And is connected to a serial port 140 provided in the sensing receiver 100,
The serial port 140 is connected in a master-slave configuration to a serial port of another sensing receiver, and collects data provided from sensors and guidance meters of other sensing receivers under the control of the MPU 110 of the sensing receiver 100 Wherein the building control system is also configured as an expansion port
delete A method of driving a building control system,
S100: the power of the sensing receiver 100 is turned on or reset to start the operation of the sensing receiver 100;
S110: The timer provided in the MPU 110 of the detection receiver 100 is set as a data collection time interval provided from the sensors and the guidance meters,
An initialization step of setting reference values of a reference value data memory 160 for comparing and judging the abnormality of data provided from sensors and guidance meters of the detection receiver to initial values;
- S120: The MPU 110 collects data provided from sensors and guidance meters of the sensing receiver by data collection time intervals set by the timer;
S130: comparing the data collected by the MPU 110 with the reference values of the reference value data memory 160 to determine whether an error has occurred;
- S140: If it is determined in step S130 that an abnormality has occurred, the MPU 110 refers to the collected data and the system information memory 150 to generate a sensor and instruction meter information in which the abnormality occurs, To the integrated control server (200) together with the address or ID of the controlled building to be controlled;
- S150: outputting an alarm signal by the MPU 110 through the field monitor / alarm unit 190 of the sensing receiver 100;
S160: determining whether the collected data collected by the MPU 110 from the sensors and the guidance meters of the detection receiver are recovered to normal by data collection time intervals set by the timer;
- S170: If it is determined that the data collected in step S160 is restored to normal, the MPU 110 blocks the alarm signal through the field monitor / alarm unit 190,
Transmitting the normal recovery code to the integrated control server 200 together with the address or ID of the control target building stored in the building data memory 180, and repeating the process from step S120 again;
And a driving method of the building control system
12. The method of claim 11,
Comparing the data collected by the MPU 110 with the reference values of the reference value data memory 160 to determine whether an abnormality has occurred, and if the collected data is determined to be normal, the MPU 110 repeats step S120;
And a driving method of the building control system
12. The method of claim 11,
The MPU 110 collects data provided from the sensor of the detection receiver and the guidance meters according to the data collection time intervals set by the timer, and judges whether the collected data is recovered to normal. If the collected data is still in the abnormal state, (110) repeats step S150;
And a driving method of the building control system
A method of driving a building control system,
S200: the operation of the integrated control server 200 is started;
S210: The server CPU 210 of the integrated control server 200 determines whether information transmitted from the sensing receiver 100 and received by the communication controller 220 exists.
S220: If it is determined that the information received in step S210 is present, the server CPU 210 reads the information received from the communication buffer 230 and displays the address of the building to which the sensing receiver 100 is installed, ID and information of the steady state sensors and guidance meters received by the sensing receiver 100 of the target building from the building information DB 240,
S230: The server CPU 210 then compares the information read from the communication buffer 230 with the information collected and retrieved from the building information DB 240, and if the information is abnormal, the abnormal state building information storage 250 The information stored in the abnormal state building information storage unit 250 in the case of the steady state information is deleted and the information stored in the abnormal state building information storage unit 250 is deleted through the status monitor output unit 270, And outputting a status of the image,
S240: Next, the server CPU 210 transmits an abnormal state of the control target building to the emergency communication network 300 stored in the subscriber mobile information memory 260 via the mobile communication unit 280 And a step of repeating the steps from step S210.
15. The method of claim 14,
The server CPU 210 of the integrated control server 200 determines whether or not the information transmitted from the detection receiver 100 and received by the communication control unit 220 exists and that the received information does not exist And the server CPU 210 repeatedly performing step S210. The method for driving the building control system

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