KR20140080738A - Building Integrated Network Management Sever and Managing Method Thereof - Google Patents

Abstract

The present invention relates to an integrated management server for a building and a managing method thereof. The integrated management server for a building in the present invention comprises: a receiving module for receiving data from a sensing device or user terminals existing in a building; an analysis module for grouping and analyzing data based on location ID of the received data; and an event module for acquiring a total data value by accumulating data grouped according to the location ID, comparing the acquired total data value with the standard value, and producing an alarm message. According to the present invention, an image, a sensor, and location information are integrated in a file system to effectively manage wired and wireless networks developing while having complexity in the building. Also, the integrated file system is transmitted to terminals of a client, a manager, and an operator in a building corresponding to the location where an event occures, thereby improving the effectiveness of management.

Description

[0001] The present invention relates to a building integrated operation management server,

The present invention relates to an integrated operation management system and its management method in a smart building, and more particularly, to a hierarchical classification of state information, location information, and image information in a building for a customer, employee, And more particularly to a building integrated operation management system and a management method thereof.

In recent years, skyscrapers have been merged with IT to form smart buildings, which are designed for automation and security purposes, such as power, lighting, and wireless sensors. Due to the development of wireless networks, the number of customers who want to use various services using wireless network infrastructure is increasing in Smart Building.

However, conventionally designed buildings focus on energy management in buildings such as Building Energy Management System (BEMS), Building Automation and Control Network (BACnet), and Building Automation System (BAS) This does not provide a method for transmitting a complex information in a building to a user using a wireless communication terminal such as a user terminal. As the wireless sensor network is constructed as an automatic control system, it provides unidirectional limited convenience for the users, so it is not enough to substitute urgent natural disasters such as earthquakes, typhoons, and topics that occur urgently. In addition, various wireless sensors, video equipment, and network equipment designed and built in a smart building are individually managed according to the use of different interfaces, causing problems such as traffic inducement, circuit complexity, and lack of economical efficiency.

As described above, wired / wireless networks in buildings are designed and constructed with diversity and complexity. As the scale of the wired / wireless networks increases, the need for efficient management and control is increasing due to overload of network traffic.

The technology of the present invention is disclosed in Korean Patent Registration No. 10-1078802 (registered on October 26, 2011).

SUMMARY OF THE INVENTION Accordingly, it is an object of the present invention to provide a building integrated operation management system and method for efficiently delivering in-building status information, location information, image information, and the like to customers, employees, .

The building integrated operation management server according to the present invention includes a reception module for receiving data from user terminals or a sensing device existing in a building, an analysis module for analyzing and grouping data based on a location ID of the received data, And an event module for accumulating data grouped by location IDs to obtain a total data value and for comparing the obtained total data value with a reference value to generate an alarm message.

The sensing device may be a disaster detection sensor, and the total data value may be frequency information of a packet received from the disaster detection sensor.

And a transmission module for transmitting the alarm message to a user terminal corresponding to the location ID.

And a storage module for storing an IP address of the user terminal corresponding to the location ID and a priority order of data grouped by the location ID.

The data received from the user terminals or the sensing device may include network data between the user terminals and the sensors installed in the building, sensor data sensed from the sensors installed in the building, image data sensed by the CCTV, The current location, and the IP address of the user terminal held by the customer.

Wherein the receiving module compares the number of packets of the received data with a threshold value and transmits packet type or command analysis to data larger than the threshold value and transmits the data to the analysis module, If the same data is image data, the image data is transmitted in the form of packet or command analysis to the analysis module. If the data smaller than or equal to the threshold value is not image data, , The packet type or command analysis may be performed and transmitted to the analysis module.

The analysis module groups the sensor data, the image data, and the customer management data, which are sensed by the same position ID, and the storage module determines a priority order of the plurality of data corresponding to the position ID through the size of the data value .

The event module may generate a total data value by applying a weight to each data according to the priority, and then summing a plurality of data corresponding to the location ID.

Wherein the transmission module transmits the alarm message to a user terminal of a customer who is close to the location ID and a user terminal of a building manager if the total data value is larger than a reference value and if the total data value is less than or equal to a reference value , And may transmit a message to the user terminal of the building manager.

The transmission module may transmit the alarm message using the IP address of the user terminal included in the customer management data.

According to another aspect of the present invention, there is provided a management method using a building integrated management server, comprising: receiving data from user terminals or a sensing device existing in a building; analyzing data based on a location ID of the received data; Determining a priority for data grouped by the location IDs and storing the data; accumulating data grouped by the location IDs to obtain a total data value; comparing the total data value with the reference value; And generating an alarm message.

According to the present invention, in order to efficiently manage a wired / wireless network that develops with complexity in a building, a video, a sensor, a location information and the like are integrated into a file system, and a customer, a manager, Or the like, thereby maximizing the efficiency of management.

In addition, it can analyze customer 's location and status information in real - time, prevent possible disasters and natural disasters in advance, and provide information in real - time according to customer' s demand.

FIG. 1 is a block diagram illustrating a building integrated operation management system using a user terminal according to an embodiment of the present invention. Referring to FIG.
2 is a block diagram of a building integrated management server shown in FIG.
FIG. 3 shows a format of building information data according to an embodiment of the present invention.
4 illustrates a transmission data packet including building information data according to an embodiment of the present invention.
5 is a flowchart illustrating a procedure of processing information collected from various sensing devices according to an embodiment of the present invention.
FIG. 6 is a diagram for explaining how an analysis module classifies data based on a user location in an integrated building management system according to an embodiment of the present invention. Referring to FIG.
FIG. 7 is a flowchart illustrating a method for transmitting an emergency event in a smart building to a user terminal according to an embodiment of the present invention. Referring to FIG.
8 shows a user table according to an embodiment of the present invention.
FIG. 9 illustrates an interface for integrated operation management of a building integrated operation management system according to an embodiment of the present invention.

Hereinafter, embodiments of the present invention will be described in detail with reference to the accompanying drawings so that those skilled in the art can easily carry out the present invention.

FIG. 1 is a block diagram illustrating a building integrated operation management system using a user terminal according to an embodiment of the present invention. Referring to FIG. As shown in FIG. 1, a user terminal in a building is classified into a user terminal 100 of a building manager, a user terminal 200 of a customer in a building, and a user terminal 300 of a network administrator. An alarm message is transmitted to the corresponding user terminal.

In addition, the user terminals 100, 200, and 300 have a mobility capable of being carried by a user and can perform signal processing on their own without intervention of the main computer while having a microprocessor and a storage device (RAM) , And includes a smart phone, a mobile phone, and a PDA. The user terminals 100, 200 and 300 communicate with the integrated building management server 400 through a wireless router and the wireless router refers to an access point (AP) to which the user terminals 100, 200 and 300 access . Also, the user terminals 100, 200, and 300 according to the embodiment of the present invention are classified according to the user who holds the user terminal, and perform substantially the same functions.

The building integrated network management server (BINMS) 400 includes a network database 600, a sensor database 700, a video database 800, a customer management database 900, And at the same time collects and analyzes customer information in the building.

Here, the network database 600 stores network states of a plurality of user terminals, sensor devices, and various servers existing in a building. The sensor database 700 is used to detect an emergency in a building. The sensor database 700 stores data values sensed from a temperature sensor, a CO ₂ sensor, and a fire sensor attached to each building. The image database 800 stores indoor image data captured through a CCTV installed in a building, and indoor images are simultaneously stored with pixel values as data values for each frame. In the customer management database 900, the current location of the customer, the IP address of the user terminal held by the customer, and the like are sensed and stored through communication between the wireless router (AP) installed in the building and the user terminal used by the customer.

In order to provide the integrated management service according to the embodiment of the present invention, the building integrated operation management server 400 requires a communication protocol for the network with the databases 600, 700, 800, and 900 which are the subordinate management objects. Accordingly, according to an embodiment of the present invention, the building integrated operation management server 400 has a separate building management protocol for communicating messages with each of the lower databases 600, 700, 800, and 900, TCP / IP-based multi-socket communication. A detailed description of the building management protocol will be described later in detail with reference to FIG.

2 is a block diagram of a building integrated management server shown in FIG.

2, the building integrated operation management server 400 includes a receiving module (not shown) for receiving network data, sensor data, image data, and customer management data from subdatabases 600, 700, 800, An analysis module 410 for analyzing and grouping data based on the location IDs of the received data, a storage module 420 for storing IP addresses of user terminals existing in the smart building, And a transmission module 440 for transmitting the generated alarm message to the user terminals 100, 200, and 300 corresponding to the location IDs.

First, the receiving module 405 uses a socket communication method based on the TCP / IP protocol from each of the sub-databases 600, 700, 800, and 900 in order to reduce the network traffic load in real- Data is received.

Table 1 below illustrates the BDU (Building Data Unit) of the CO ₂ data and the temperature data, which is one of the sensor data having the greatest real-time transmission load among the sub databases 600, 700, 800 and 900.

As shown in Table 1, the sensor database 700 stores packet data for each sensing device type, and the stored data is transmitted to the analysis module 410. Here, the sensing device is a disaster detection sensor that can prevent earthquake, fire, etc., and includes an earthquake sensor, a CO ₂ sensor, a temperature sensor, and the like.

The sensor database 700 stores the CO ₂ data sensed corresponding to the management event occurrence time (Time), the data value sensed by the sensing device, the device ID, and the installed location ID do.

As shown in Table 1, by storing the creation date and time of sensing collection information in the sensing index (Time index), the manager can designate the validity period of the information. In addition, device IDs unique to the sensor device can be used to identify the function of the device and systematic device management is possible.

Communication between the subordinate databases 600, 700, 800, and 900 existing in the building and the building integrated operation management server 400 is performed through a TCP / IP-based network 100 through a building information packet having a fixed length of 33 bytes as shown in FIG. It is done in the environment.

FIG. 3 shows a format of building information data according to an embodiment of the present invention.

In FIG. 3, 'Start of Building Data (SBD)' has a length of 2 bytes and indicates the beginning of a building data packet. The 'Type' has a length of 4 bytes, and the contents of the packet type according to the Type are as shown in Table 2.

Type Data Description 0x10 CO ₂ 0x20 Temperature 0x30 Humidity 0x40 Acceleration

In addition, 'Config. (Configuration) 'is a packet processing instruction having a length of 1 byte, indicating whether data is transmitted or lost, and' Length 'has a length of 2 bytes and indicates a packet length. As shown in Table 1, 'BDU (Building Data Unit)' has a fixed length of 20 bytes, including a Time having a length of 5 bytes, a Data value having a length of 4 bytes, a Device ID having a length of 6 bytes, And a location ID having a byte.

Here, Time represents the sensing time of data such as CO ₂ data and temperature data, and the data value is represented only as a real value as the value of the sensed data. Also, the device ID (Device ID) is an identification mark for identifying the sensing device, and the Location ID is an identification mark for identifying the installation position of the sensing device.

3, 'CRC' has a length of 2 bytes and indicates whether an error is detected using CRC-16. 'EBD (End of Building Data)' has a length of 2 bytes and is defined as a function of the last indication of a packet .

4 illustrates a transmission data packet including building information data according to an embodiment of the present invention.

As shown in FIG. 4, since all data communication according to the embodiment of the present invention operates in a TCP / IP based environment, building information data (Building Information Data) generated in the application layer of the lower databases 600, 700, After passing through the transport layer, an encapsulation process of adding an IP header at the network layer is performed to generate a transport data packet as shown in FIG.

4, the source IP is an IP address of each of the sub-databases 600, 700, 800, and 900 that generate and transmit data, and a destination IP address is an IP address of the integrated integrated management server 400 . The IP header of the building information packet data shown in FIG. 4 is not limited to IPv4 but is applicable to IPv6, and the source IP address and the destination IP address are the same as IPv4.

5 is a flowchart illustrating a procedure of processing information collected from various sensing devices according to an embodiment of the present invention. 5 is a flowchart illustrating a procedure in which transmission data packets of the type shown in FIG. 4 generated through each of the lower databases 600, 700, 800, and 900 are processed by a building management protocol.

5, the receiving module 505 receives a transmission data packet from each of the lower databases 600, 700, 800 and 900 (S510) and counts the number of transmission data packets collected for each lower database S520). That is, the number of transmission data packets received for each of sensor data, image data, and customer management data is accumulated.

Next, the receiving module 505 compares the number of transmission data packets having the largest number of types with the threshold value set in the building management protocol (S530). If a certain type of transmission data packet is continuously transmitted and exceeded a threshold due to a specific situation, the received transmission data packet is processed prior to a packet generated in another lower database.

For example, when the temperature of a specific area suddenly rises, the receiving module 505 compares the number or size of the received sensor data packets with the threshold because the sensor data packet related to the temperature will be received the most.

In this manner, the receiving module 505 sequentially analyzes and verifies the packet type of the transmission data packet having a value higher than the threshold value, the Config command, and the variable length BDU, and then proceeds to error detection (S540). Then, the transmission data packet in which no error is detected is preferentially transmitted to the analysis module 410 (S550).

If the size of the received transmission data packet is smaller than or equal to the threshold value in step S503, the reception module 405 determines whether the received data is image data (S560). If the size of the received transmission data packet is image data, After analyzing and verifying BDUs of variable length in order, error detection proceeds (S540).

If the received data is not image data, that is, if the received data is sensor data, customer management data, or network data, the receiving module 505 collects data packets in the buffer in operation S570. In step S540, the data packet is collected after the data packet of a predetermined size or more is collected.

The reason why the video data is preferentially processed is because the video data has the largest packet size and the shortest collection time in comparison with other data.

As described above, the receiving module 505 can transmit data packets according to the data collection period of each lower-level equipment through the packet priority processing algorithm of the building management protocol, thereby enabling quick and efficient data processing. In addition, by storing sensor and customer information packets with high frequency of data occurrence in a buffer and collectively processing them, it is possible to prevent traffic load of a link, prevent packet loss and errors in advance.

Meanwhile, the network data may use Simple Network Management Protocol (SNMP), Common Management Information Protocol (CMIP), or the like as a management protocol for transmitting network information separately from the building management protocol according to the embodiment of the present invention.

FIG. 6 is a diagram for explaining how an analysis module classifies data based on a user location in an integrated building management system according to an embodiment of the present invention. Referring to FIG. As shown in FIG. 6, the analysis module 410 analyzes the sensor data 701, the video data 801 using the CCTV, and the customer information data 901, which are operated based on the TCP / IP multi-socket.

Here, the sensor data 701 includes a location ID, a device ID, a date, and a sensor value of the sensor. The image data 801 includes a location ID, an equipment ID, and a data value of the CCTV. Includes the customer's location ID, MAC address, date, and customer information.

Then, the analysis module 410 analyzes the received transmission data packet using the position filter 411, and arranges and analyzes the received transmission data packet based on the acquired position ID, and transmits the packet to the storage module 420. That is, the analysis module 410 analyzes the sensor data 701, the image data 801, and the customer information data 901, and groups the data corresponding to the corresponding location ID.

6, the sensor data {LOC [A] _ 1, Dev CO, Time # 1, Value # 1}, the image data {LOC [A] _ 1, Dev ID , Data}, and the customer management data {LOC [A] _ 1, MAC # 3, Time # 3, Info # 3} form one group. In the case of LOC [B] _2, the sensor data {LOC [B] _2, Dev O, Time # 2, Value # 2}, customer management data {LOC [B] _2, MAC # Info # 1} form one group.

The storage module 420 is managed according to the access right of the user, and in principle, only the super administrator configures and manages the logical schema. Other information can be accessed and retrieved through the user view of the network administrator and the customer.

Table 3 below shows an example of a database stored and managed in the storage module 420 on the basis of the location ID. The priority information, the data value, the status, the sensing device, and the sensing time corresponding to the location ID are stored. According to the embodiment of the present invention, data can be classified on the basis of location information, and when there is a request for data of a user, information closest to the user location information can be provided first. Therefore, unnecessary data transmission can be blocked, Can be used.

In Table 3, the priority is determined according to the collected data value, and the data is managed through the classification of 1 to 3 according to the importance of management. The state is an index for grasping the state of the sensing device based on the threshold value of each lower management data, thereby providing convenience of data analysis and management of the building manager and the network manager. Here, the sensing device includes not only a CO ₂ sensor, a temperature sensor but also an image sensor device such as a CCTV.

According to the embodiment of the present invention, the compatibility of the mobile OS is improved by using the MPEG 4 format for the video data, and the ease of use in the wireless mobile environment can be improved by using a coding standard such as H.264.

Next, the event module 430 serves as an intermediate layer between the storage module 420 and the transmission module 440 and classifies the transmission method and the object when an event such as a user's request or emergency failure occurs.

Hereinafter, a process of determining whether an event module and a transmission module are events based on collected data packets and transmitting an event occurrence to an external user terminal will be described with reference to FIG.

FIG. 7 is a flowchart illustrating a method of transmitting an emergency event in a smart building to a user terminal according to an exemplary embodiment of the present invention, and FIG. 8 illustrates a user table according to an embodiment of the present invention.

7, according to an embodiment of the present invention, when an emergency event such as a fire in a smart building, an earthquake, or a network failure occurs, information is collected from various devices and information is transmitted to a smart device in a building Fig.

7, the event module 430 receives data corresponding to the location ID in the Smart Building as shown in Table 3 from the analysis module 410 (S710). Here, the event module 430 may receive data from the analysis module 410 or receive data through the storage module 420.

Then, the event module 430 sums the data (video data, sensor data, and customer management data) corresponding to the same position ID but of different types to generate a total data value (S720). Here, the total data value is frequency information of the transmission data packet received from the sensing device, and may be generated by weighting the data according to the type or priority of the data.

The event module 430 compares the total data value with the reference value in step S730. If the total data value is greater than the reference value, the event module 430 transmits the total data value to the user terminal corresponding to the corresponding location ID through the transmission module 440 An alarm message is transmitted (S740).

For example, when the total data value is larger than the reference value in the area where the location ID is LOC [A] _1, an alarm signal is transmitted to the user terminal 200 of the customer and the user terminal 100 of the building manager around the area So that the emergency situation can be notified. Here, the alarm signal may be transmitted to the user terminal 300 of the network manager.

At this time, the current location of the customer is received through the customer management data 901, and the customer management data includes the current location of the customer and the IP address of the user terminal possessed by the customer. That is, the current position of the customer and the IP address of the user terminal possessed by the customer can be sensed through the wireless router installed in the user terminal 200 owned by the customer and the intra-building section. Accordingly, the storage module 420 stores the MAC address and Uaddr information of the user terminal in the form of a user table as shown in FIG.

On the other hand, if the total data value is smaller than or equal to the reference value, the alarm message is transmitted only to the user terminal 100 of the building manager (S750). Here, the user terminal that transmits the alarm message according to the comparison result is variously classified according to the internal situation in the smart building and the request of the building manager.

In this way, alarm messages can be quickly replaced with an alarm in case of an emergency, and unnecessary redundant data and traffic load can be prevented by providing differential information.

On the other hand, the MAC address is a physical identification address for providing differentiated information to a specific customer and is individually assigned to the user terminal 100, 200, 300 of the building manager, the customer in the building, and the network administrator. Through the MAC address, the transmission module 440 can efficiently transmit information on the current situation to a customer, a building manager, a network manager, or the like located in an area where an alarm occurs.

However, since the number of the user terminals 200 in the building is limited according to the purpose of use of the building, it is a principle to register the MAC address only in a customer who desires premium building information. In this case, The MAC address is stored in the storage module 420. That is, the IP address of the user terminal accessing the adjacent wireless router through the wireless router installed in the building is automatically stored in the storage module 420.

According to the embodiment of the present invention, an alarm message is transmitted based on an event occurrence location in a building, so that it is possible to quickly cope with a failure in a building and a natural disaster, and each building information data is classified based on a location ID. The information generated around the user location can be more accurately provided.

In addition, when a network failure occurs in the building, the event module 430 can detect the failure location and the failure type of the equipment in the building through the network database 600. When a network failure is detected, the event module 430 can fuse information such as a failure occurrence location in a building, a failure type, and a failure occurrence time based on the database of the storage module 420.

The failure status detected by the event module 430 is transmitted to the user table 480 included in the transmission module 440. The failure status is confirmed through the manager MAC address of the network administrator's fixed IP address, Information for coping can be transmitted and information can be quickly provided to the network manager around the same location.

According to the embodiment of the present invention, it is possible to reduce load on a building network by judging whether or not an alarm is generated by fusing data, and it is possible to promptly respond by transmitting fault information according to a classification defined when a fault occurs.

FIG. 9 illustrates an interface for integrated management of a building integrated operation management system according to an embodiment of the present invention, and shows an interface displayed on a screen of a user terminal 100 of a building manager.

9, the user terminal 100 of the building manager includes an interface 101 for indicating the status of the wireless sensor data, an interface 102 for indicating the status of the video data, an interface 103 for indicating the status of the network data, Is displayed.

The interface 101 of the wireless sensor data arranged at the upper left of the screen is displayed in various graph formats having graphical elements for displaying real-time status.

Also, the video data interface 102 uses a real time stream protocol from the building integrated operation management server 400, and the interface of the video data can be changed according to the user's request.

In addition, the interface 103 of the network data sets menus such as device search, ping test, equipment control, NMS monitoring, error log check, and warning log check, thereby enabling quick response in the event of a failure. In addition, the network data interface 103 enables the monitoring of the network in real time through the CPU load of the integrated building management server 400 and the TCP / IP status check.

As described above, according to the embodiment of the present invention, it is possible to integrate images, sensors, location information, and the like into a file system in order to efficiently manage a wired / wireless network that develops with complexity in a building, It maximizes the efficiency of management by transmitting to user terminal such as customer, manager and operator.

In addition, it can analyze customer 's location and status information in real - time, prevent possible disasters and natural disasters in advance, and provide information in real - time according to customer' s demand.

While the present invention has been described with reference to exemplary embodiments, it is to be understood that the invention is not limited to the disclosed embodiments, but, on the contrary, is intended to cover various modifications and equivalent arrangements included within the spirit and scope of the appended claims. Accordingly, the true scope of the present invention should be determined by the technical idea of the appended claims.

100: a user terminal of a building manager, 200: a user terminal of a customer in a building,
300: a user terminal of the network manager, 400: a building integrated operation management server,
405: Receiving module, 410: Analysis module
420: storage module, 430: event module
440: transmission module, 600: network database,
700: sensor database, 800: image database,
900: Customer Management Database

Claims (20)

A receiving module for receiving data from user terminals or a sensing device existing in a building,
An analysis module for analyzing and grouping data based on the location IDs of the received data, and
And an event module for accumulating data grouped by the location IDs to obtain a total data value and for comparing the obtained total data value with a reference value to generate an alarm message. The method according to claim 1,
Wherein the sensing device is a disaster detection sensor,
Wherein the aggregate data value is frequency information of a packet received from the disaster detection sensor. The method according to claim 1,
And a transmission module for transmitting the alarm message to a user terminal corresponding to the location ID. The method of claim 3,
And a storage module for storing an IP address of the user terminal corresponding to the location ID and a priority for data grouped by the location ID. 5. The method of claim 4,
The data received from the user terminals or the sensing device,
The network data between the user terminals and the sensors installed in the building, the sensor data sensed by the sensors installed in the building, the image data captured by the CCTV, the current location of the customer, and the IP address of the user terminal The integrated management server comprising: 6. The method of claim 5,
The receiving module includes:
Accumulates the number of packets of the received data and compares the number of packets with the threshold value, and transmits packet type or command analysis to data greater than the threshold value to the analysis module,
If the data smaller than or equal to the threshold value is image data, the analyzing module performs packet type or command analysis and transfers the data to the analysis module. If the data smaller than or equal to the threshold value is not image data, And then transmits the packet type or command analysis to the analysis module. The method according to claim 6,
Wherein the analysis module comprises:
The sensor data, the image data, and the customer management data sensed by the same position ID are grouped,
Wherein the storage module comprises:
And determines a priority order of the plurality of data corresponding to the location ID through the size of the data value. 8. The method of claim 7,
Wherein the event module comprises:
And applying the weight to each data according to the priority, and summing a plurality of data corresponding to the location ID to generate the total data value. 9. The method of claim 8,
The transmission module comprises:
If the total data value is greater than a reference value, transmitting the alarm message to a user terminal of a customer close to the location ID and a user terminal of a building manager,
And transmits a message to the user terminal of the building manager if the total data value is less than or equal to a reference value. 10. The method of claim 9,
The transmission module comprises:
And transmits the alarm message using the IP address of the user terminal included in the customer management data. Receiving data from user terminals or sensing devices present in the building,
Analyzing and grouping data based on the location ID of the received data;
Determining and prioritizing data grouped by the location IDs, and
Accumulating data grouped by the position IDs to obtain a total data value, and generating an alarm message by comparing the obtained total data value with a reference value. 12. The method of claim 11,
Wherein the sensing device is a disaster detection sensor,
Wherein the total data value is frequency information of a packet received from the disaster detection sensor. 12. The method of claim 11,
And transmitting the alarm message to a user terminal corresponding to the location ID. 14. The method of claim 13,
Further comprising storing an IP address of the user terminal corresponding to the location ID and a priority for data grouped by the location ID. 15. The method of claim 14,
The data received from the user terminals or the sensing device,
The network data between the user terminals and the sensors installed in the building, the sensor data sensed by the sensors installed in the building, the image data captured by the CCTV, the current location of the customer, and the IP address of the user terminal Wherein the management information includes at least one of the customer management data and the customer management data. 16. The method of claim 15,
Wherein the receiving the data comprises:
Accumulating the number of packets of the received data and comparing the accumulated number of packets with a threshold value, analyzing a packet type or command for data larger than the threshold value,
If the data smaller than or equal to the threshold value is image data, packet type or command analysis is performed. If the data smaller than or equal to the threshold value is not image data, , A management method using a building integrated operation management server that performs packet type or command analysis. 17. The method of claim 16,
The step of analyzing and grouping data based on the location IDs of the received data may include grouping sensor data, image data, and customer management data sensed by the same location ID,
Wherein the step of determining and storing a priority order of data grouped by the location IDs comprises: determining a priority order of a plurality of data items corresponding to the location IDs based on a size of a data value, . 18. The method of claim 17,
Wherein the generating of the alarm message comprises:
And applying a weight to each data according to the priority order, and summing a plurality of data corresponding to the location ID to generate the total data value. 19. The method of claim 18,
Wherein the transmitting the alarm message to a user terminal corresponding to the location ID comprises:
If the total data value is greater than a reference value, transmitting the alarm message to a user terminal of a customer close to the location ID and a user terminal of a building manager,
And transmitting a message to the user terminal of the building manager if the total data value is less than or equal to a reference value. 20. The method of claim 19,
Wherein the transmitting the alarm message to a user terminal corresponding to the location ID comprises:
And transmitting the alarm message using the IP address of the user terminal included in the customer management data.

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