KR102614722B1 - System for Controlling Facilities using Module Wireless Communication - Google Patents

Abstract

The present invention relates to a facility control system utilizing wireless communication for each module that divides multiple facilities into relay servers and modules and controls multiple relay servers from the main server. Specifically, the equipment and equipment installed in a building. It is formed in the device and includes a driving server that controls the equipment, a relay server that communicates wirelessly with a plurality of driving servers, and a main server that communicates wirelessly with a plurality of relay servers.

Description

Facility control system using wireless communication for each module {System for Controlling Facilities using Module Wireless Communication}

The present invention relates to a facility control system utilizing wireless communication for each module that divides multiple facilities into relay servers and modules and controls the multiple relay servers from the main server.

Patent Document 001 is a system that integrates the collected data into a local active black box rather than having a central control server in a remote location to include the functions of an active black box and a central control server, and can store and view the collected data on its own. In the factory equipment monitoring system using a local active black box (10) by operating a built-in collection server, PLC (Programmable Logic Controller) operation data of the factory equipment is collected and real-time video data from the connected CCTV for filming the operating status of the factory equipment. Collects real-time temperature/humidity data on factory equipment from a temperature/humidity sensor, collects data on hazardous substances generated from factory equipment from a gas sensor and stores it as an expansion memory device, and collects data on factory equipment including an identification ID. When self-generating control information or receiving factory equipment control information including an identification ID from a mobile terminal, a local active black box controls PLC operation of factory equipment corresponding to the identification ID; If the factory equipment performs an operation other than the preset operation by the local active black box, the malfunction event information or line status event information generated when the malfunction event information or line status event information including the identification ID corresponding to the factory facility is generated. It stores PLC operation data, real-time video data, temperature/humidity data, and hazardous substance data by the local active black box, and later uses the data saved by the local active black box to identify each identification ID of factory equipment. An expansion memory device that provides functions to monitor time-series trend changes; and n (n is a natural number of 2 or more), and can be formed by matching at least one factory facility for each factory facility. PLC drive data, real-time video data, and real-time video data for each identification ID of each factory facility from the local active black box. Temperature/humidity data and hazardous substance data are received and time-series trend changes are monitored. When malfunction event information or line status event information is received, the corresponding factory equipment location coordinates, equipment name, and equipment operation status are output. , a mobile terminal that transmits factory equipment control information input from the manager to a local active black box.

Patent Document 002 relates to an automated facility installed with a facility controller that collects various operating information, in which work details on a workpiece are recorded as numerical data, work is performed according to this numerical data, a workpiece is produced, and the device is connected to the facility controller. A first wireless communicator through which data information is transmitted, a wireless repeater through which data information is communicated wirelessly with the first wireless communicator at a short distance, and a second wireless repeater through which data information is communicated wirelessly at a short distance through the relay role of the wireless repeater. It presents a technology that consists of a wireless communication system that allows the operating information of automated equipment to be checked regardless of location and controlled remotely.

Patent Document 003 relates to an automated facility installed with a facility controller that collects various operation information, in which work details on a workpiece are recorded as numerical data, work is performed according to this numerical data, a workpiece is produced, and the device is connected to the facility controller. A first wireless communication device through which data information is transmitted; a wireless repeater that communicates data information wirelessly with the first wireless communicator at a short distance; And a second wireless communication device that performs the relay role of the wireless repeater and communicates data wirelessly at a short distance.

Patent document 004 is a full-speed communication device consisting of a full-speed communication device; And a series of processes are repeated continuously, including a post-equipment controller that is connected to a post-equipment communicator that communicates wirelessly with the pre-equipment communicator and collects and operates equipment information while transmitting and receiving data from the post-equipment communicator. As a result, a technology is proposed in which data on the completion of a product is transmitted and received through wireless communication.

KR 10-2018-0095346 A (August 27, 2018) KR 10-2019-0046156 A (May 7, 2019) KR 10-2006-0115059 A (November 8, 2006) KR 10-2006-0110949 A (October 26, 2006)

The present invention relates to a facility control system utilizing wireless communication for each module that divides multiple facilities into relay servers and modules and controls the multiple relay servers from the main server.

It is intended to solve the problems of prior inventions, and the present invention relates to a facility control system using wireless communication for each module, including a facility device 100 installed in a building 10; A driving server 200 formed in the equipment 100 and controlling the equipment 100; A relay server (300) that communicates wirelessly with a plurality of the driving servers (200); It consists of a main server (400) that communicates wirelessly with a plurality of the relay servers (300).

The present invention relates to a facility control system utilizing wireless communication for each module, and includes the facility device 100 presented above; Drive server (200); Relay server (300); To the invention consisting of the main server 400, a measurement sensor 500 is added, which is formed in the building 10 and measures a selected one of air quality, water level, temperature, and humidity.

The present invention relates to a facility control system utilizing wireless communication for each module, and includes the facility device 100 presented above; Drive server (200); relay server (300); The invention consists of a main server 400; a temperature control device 110 formed in the equipment 100 and controlling the temperature; A ventilation device 120 that controls air quality inside the building 10; A water level control device 130 that controls the water level underground of the building 10 is added.

The present invention relates to a facility control system utilizing wireless communication for each module, and includes the facility device 100 presented above; Drive server (200); Relay server (300); The invention consists of a main server (400); a wireless communication device (210) formed on the driving server (200) and communicating wirelessly with the relay server (300); A facility control device 220 that controls the facility device 100 by the wireless communication device 210 is added.

The present invention relates to a facility control system utilizing wireless communication for each module, and includes the facility device 100 presented above; Drive server (200); Relay server (300); The invention consists of a main server (400); a first communication device (310) formed on the relay server (300) and communicating wirelessly with the driving server (200); a second communication device (320) that communicates wirelessly with the main server (400); A relay control device 330 that controls the first communication device 310 and the second communication device 320 is added.

The present invention relates to a facility control system utilizing wireless communication for each module, and includes the facility device 100 presented above; Drive server (200); Relay server (300); In the invention consisting of a main server 400, the first communication device 310 and the second communication device 320 are each formed by a short-distance communication method selected from Wi-Fi, ZigBee, Bluetooth, and RF methods, and are of different types. Sending and receiving information through short-distance communication is added.

The present invention relates to a facility control system utilizing wireless communication for each module, and includes the facility device 100 presented above; Drive server (200); Relay server (300); The invention consists of a main server 400; a storage unit 331 formed in the relay control device 330 and storing information of the first communication device 310; A conversion unit 332 is formed in the storage unit 331 and converts the short-range communication method of the first communication device 310 to the short-range communication method of the second communication device 320.

The present invention relates to a facility control system utilizing wireless communication for each module, and includes the facility device 100 presented above; Drive server (200); Relay server (300); The invention consists of a main server 400; a main communication unit 410 formed in the main server 400 and communicating wirelessly with a plurality of the relay servers 300; an information storage unit 420 formed in the main communication unit 410 and storing information received from a plurality of relay servers 300; An auxiliary current supply unit 430 that supplies auxiliary power to maintain communication during a power outage is added.

The present invention relates to a facility control system utilizing wireless communication for each module, and includes the facility device 100 presented above; Drive server (200); Relay server (300); An artificial intelligence server 440 formed in the main server 400 and controlling the relay server 300 according to the information measured by the measurement sensor 500 is added to the invention consisting of the main server 400. do.

The present invention relates to a facility control system utilizing wireless communication for each module, and includes the facility device 100 presented above; Drive server (200); Relay server (300); The invention consists of a main server 400; a setting unit 441 formed in the artificial intelligence server 440 and setting a reference value for controlling the equipment 100; A comparison unit 442 that compares the reference value set in the setting unit 441 with the measurement value measured by the measurement sensor 500; A control unit 443 that controls each of the plurality of equipment 100 according to the information compared by the comparison unit 442 is added.

The present invention allows one relay server to divide multiple facilities into modules and effectively control the multiple facilities from the main server.

The present invention allows multiple facilities and relay servers to communicate wirelessly, thereby reducing construction costs, material costs, and labor costs.

The present invention can prevent communication errors by differentiating the short-distance communication method for wirelessly communicating between a plurality of facilities and a relay server and the short-distance communication method for wirelessly communicating between a plurality of relay servers and the main server.

The present invention can predict equipment risks and effectively control equipment.

Figure 1 is a conceptual diagram showing a building in which a facility control system using wireless communication for each module of the present invention is installed.
Figure 2 is a cross-sectional view showing a facility control system utilizing wireless communication for each module of the present invention.
Figures 3 and 4 are block diagrams showing a facility control system using wireless communication for each module of the present invention.

Hereinafter, the most preferred embodiments of the present invention will be described in detail in order to enable those skilled in the art to easily practice the present invention.

Numbers cited in the examples below are not limited to the objects of citation and can be applied to all examples. An object that has the same purpose and effect as the configuration presented in the examples is an equivalent replacement object. The high-level concept presented in the examples includes low-level concept objects that are not described.

(Example 1-1) The present invention provides a facility control system utilizing wireless communication for each module, including: a facility device 100 installed in a building 10; A driving server 200 formed in the equipment 100 and controlling the equipment 100; A relay server (300) that communicates wirelessly with a plurality of the driving servers (200); It includes a main server (400) that communicates wirelessly with a plurality of the relay servers (300).

(Example 1-2) In Example 1-1, the facility control system utilizing wireless communication for each module of the present invention is formed in the building 10 and measures one selected from air quality, water level, temperature, and humidity. It includes a measurement sensor 500 that performs.

(Example 1-3) In Example 1-2, the facility control system utilizing wireless communication for each module of the present invention is one in which the building 10 is formed of a selected one of a building, an apartment, a gym, a factory, and a warehouse. Includes ;

(Example 1-4) In Example 1-1, the facility control system utilizing wireless communication for each module of the present invention is, wherein the relay server 300 is formed in sections of the same size on the floor of the building 10. includes;

(Example 1-5) In Example 1-1, the facility control system utilizing wireless communication for each module of the present invention includes, wherein the relay server 300 is formed by being embedded and exposed in the wall and floor. do.

(Example 1-6) In Example 1-1, the facility control system utilizing wireless communication for each module of the present invention has at least one main server 400 installed indoors or outdoors in the building 10. includes;

The present invention relates to a facility control system utilizing wireless communication for each module, and specifically, for controlling facility equipment 100 installed in a plurality of rooms formed in a building 10, an underground parking lot, etc., for each module. Referring to FIGS. 1 and 2, the equipment control system utilizing wireless communication for each module is a relay server ( 300 communicates wirelessly, and the plurality of relay servers 300 are controlled by the main server 400 through wireless communication. At this time, the relay server 300 divides the location where the equipment 100 is installed into a plurality of sections and forms a plurality of locations. The relay server 300 is for controlling a plurality of equipment 100, and a plurality of relay servers 300 are formed in the building 10 to control the plurality of equipment 100. At this time, the relay server 300 controls one of the plurality of equipment devices 100 based on air quality, water level, temperature, humidity, etc. measured by the measurement sensor 500 installed in the building 10. Accordingly, when the water level of the sump formed in the underground parking lot rises, the relay server 300 at the location where the sump is installed controls the pump of the sump to adjust the water level along with an alarm.

And the plurality of relay servers 300 are controlled by one main server 400. The main server 400 is installed inside the building 10 or is installed inside the building 10 to manage the plurality of buildings 10. Can be installed outside of. In addition, since the main server 400 and the relay server 300 communicate wirelessly, the cable construction process can be reduced, thereby saving material and labor costs.

(Example 2-1) The present invention relates to a facility control system utilizing wireless communication for each module. In Example 1-1, it is formed on the hot wire, is formed on the facility device 100, and controls the temperature. A temperature control device (110) for controlling; A ventilation device 120 that controls air quality inside the building 10; It includes a water level control device 130 that controls the water level in the basement of the building 10.

(Example 2-2) In Example 2-1, the facility control system utilizing wireless communication for each module of the present invention is an air circulation device that circulates the air inside the building (10). What is formed; includes.

(Example 2-3) In Example 2-1, the facility control system utilizing wireless communication for each module of the present invention is the water level control device 130 installed in at least one water sump well installed in the building 10. It includes a pump that regulates the water level.

(Example 2-4) In Example 2-2, the equipment control system using wireless communication for each module of the present invention is configured to control the equipment 100 selected from air quality, temperature, humidity, and water level of the building 10. Includes an alarm device that warns if one rises.

(Example 2-5) In Example 2-4, the facility control system utilizing wireless communication for each module of the present invention includes, wherein the alarm device warns with one selected from sound, light, and communication.

The present invention relates to a facility device 100, and specifically, the facility device 100 is driven according to the air quality, temperature, humidity, and water level of the building 10 measured by the measurement sensor 500. This equipment 100 is formed of an air circulation device that controls the air quality of the building 10, a temperature and humidity control device that controls temperature and humidity, a sump that stores rainwater, and a pump that drains water from the sump. do. In addition, the equipment 100 is driven according to the air quality, temperature, and humidity of the building 10 measured by the measurement sensor 500, and the water level of the sump where rainwater flows in and is stored. At this time, the equipment 100 installed in the building 10 is controlled for each section by the relay server 300 divided by section. To explain this in detail, when the water level in the water collection well installed in the building 10 rises, the pump is driven to control the water level, and if the air quality is judged to be poor, the air is circulated and purified.

In addition, the equipment 100 is configured with an alarm device that warns the user through sound, light, communication, etc. when the information measured by the measurement sensor 500 belongs to a high-risk group.

(Example 3-1) The present invention relates to a facility control system utilizing wireless communication for each module. In Example 2-1, it is formed in the driving server 200, and is connected to the relay server 300 and wirelessly. A wireless communication device 210 that communicates; It includes a facility control device 220 that controls the facility device 100 by the wireless communication device 210.

(Example 3-2) In Example 3-1, the equipment control system utilizing wireless communication for each module of the present invention includes the driving server 200 being installed in each equipment device 100; Includes.

(Example 3-3) In Example 3-1, the facility control system utilizing wireless communication for each module of the present invention is one or more selected from Wi-Fi, ZigBee, Bluetooth, and RF methods. It includes short-distance wireless communication.

The present invention relates to the driving server 200, and specifically, the driving server 200 is installed in the equipment 100 and controls the equipment 100 through wireless communication with the relay server 300. This driving server 200 is installed in each equipment 100 and drives the equipment 100. And the driving server 200 is formed with a wireless communication device 210 that communicates with the relay server 300, and the wireless communication device 210 communicates with the relay server 300 through various short-distance wireless devices such as Wi-Fi, ZigBee, Bluetooth, and RF methods. It is the transmission and reception of information through communication. At this time, the short-distance wireless communication method is determined by the relay server 300, and the plurality of relay servers 300 are formed through the same type of short-distance communication or each communicates with the driving server 200 through different types of short-distance wireless communication. This can prevent errors from occurring due to communication overlapping. And the driving server 200 is formed with a facility control device 220 to drive the facility 100 and turns the facility 100 on/off based on information controlled by the relay server 300.

(Example 4-1) The present invention relates to a facility control system utilizing wireless communication for each module. In Example 3-1, it is formed in the relay server 300, and is connected to the drive server 200 and wirelessly. A first communication device 310 that communicates with; a second communication device (320) that communicates wirelessly with the main server (400); It includes a relay control device 330 that controls the first communication device 310 and the second communication device 320.

(Example 4-2) In Example 4-1, the facility control system utilizing wireless communication for each module of the present invention is, wherein the first communication device 310 and the second communication device 320 are each connected to Wi-Fi, It includes one formed by short-distance communication selected from Zigbee, Bluetooth, and RF methods.

(Example 4-3) In Example 4-2, the facility control system utilizing wireless communication for each module of the present invention is different from each other. Includes sending and receiving information through a type of short-distance communication.

The present invention relates to the relay server 300. Specifically, the relay server 300 controls a plurality of equipment 100 by section, and the plurality of relay servers 300 are controlled by the main server 400. It will happen. Referring to FIG. 4, this relay server 300 includes a first communication device 310 that communicates wirelessly with the driving server 200 and a second communication device 320 that communicates wirelessly with the main server 400. In addition, the first communication device 310 and the second communication device 320 are each formed of different types of short-distance communication, thereby preventing communication from overlapping. To explain this in detail, when the driving server 200 and the relay server 300 communicate wirelessly in the RF method, the driving server 200 is formed in the same quantity as the plurality of equipment 100 and transmits a large amount of the RF method. Transmission occurs. At this time, if the relay server 300 and the main server 400 also communicate wirelessly using the RF method, a communication error may occur, so the relay server 300 and the main server 400 use Bluetooth, Wi-Fi, and Zigbee instead of the RF method. This is to prevent communication errors from occurring as information is sent and received through various types of short-distance communication.

(Example 5-1) The present invention relates to a facility control system utilizing wireless communication for each module. In Example 4-1, it is formed in the relay control device 330, and the first communication device 310 ) storage unit 331 for storing information; It is formed in the storage unit 331 and includes a conversion unit 332 that converts the short-range communication method of the first communication device 310 to the short-range communication method of the second communication device 320.

(Example 5-2) In Example 5-1, the equipment control system utilizing wireless communication for each module of the present invention is the storage unit 331 in the driving state and the measurement state of the equipment 100. Includes storing measured measurement information.

The present invention relates to the relay control device 330, and specifically, the relay control device 330 stores information received from the driving server 200 and transmits it to the main server 400. This relay control device 330 converts different types of short-distance communications because the first communication device 310 and the second communication device 320 transmit information through different types of short-distance communications. In general, short-distance communication methods are formed differently depending on the type, so the method is to convert them to prevent errors from occurring. To explain this in detail, when the first communication device 310 performs wireless communication using RF method using frequency, the second communication device 320 performs wireless communication using Wi-Fi, so the first communication device 310 The information received from ) is stored in the storage unit 331 of the relay server 300 and stored temporarily. And when the short-distance communication method is converted in the conversion unit 332, the information stored in the storage unit 331 is transmitted to the main server 400 by the second communication device 320. Conversely, when the main server 400 controls the driving server 200, information is stored in the storage unit 331 and the short-distance communication method is converted in the conversion unit 332 before transmission.

(Example 6-1) The present invention relates to a facility control system utilizing wireless communication for each module. In Example 5-1, it is formed in the main server 400 and includes a plurality of relay servers 300. A main communication unit 410 that communicates wirelessly with; an information storage unit 420 formed in the main communication unit 410 and storing information received from a plurality of relay servers 300; It includes an auxiliary current supply unit 430 that supplies auxiliary power to maintain communication in the event of a power outage.

(Example 6-2) In Example 6-1, the facility control system utilizing wireless communication for each module of the present invention is the main communication unit 410 using the same short-distance communication method as the second communication device 320. Formed to communicate wirelessly; includes.

(Example 6-3) In Example 6-1, the equipment control system utilizing wireless communication for each module of the present invention includes the information storage unit 420 to record the driving state of the equipment 100 and the measurement sensor ( 500) and storing the measured values.

The present invention relates to the main server 400, and specifically, the main server 400 communicates with a plurality of relay servers 300 to store information. Referring to FIG. 3, at least one main server 400 is installed indoors or outdoors of the building 10 and controls a plurality of relay servers 300. At this time, the main server 400 communicates wirelessly with the second communication device 320 of the plurality of relay servers 300 using various methods such as Wi-Fi, Zigbee, Bluetooth, and RF. As it is formed wirelessly, the material cost during construction is reduced. , cost reduction is achieved through reduction of labor costs and construction period. Additionally, the main communication unit 410 can receive external temperature and weather conditions in conjunction with the Korea Meteorological Administration, which is used to predict the amount of rain.

In addition, the main server 400 is formed with an information storage unit 420 that stores information received from a plurality of relay servers 300, and the information storage unit 420 stores the operating status of the equipment 100 and measurement sensors ( Each measurement value measured in step 500) is stored and used as information to predict the air quality, temperature, humidity, water level of the sump, etc. of the building 10.

In addition, the main server 400 is formed with an auxiliary current supply unit 430 that supplies auxiliary power in order to maintain wireless communication in the event of a power outage, thereby controlling the operation of the equipment 100 in the event of a power outage to reduce damage. will be.

(Example 7-1) The present invention relates to a facility control system utilizing wireless communication for each module. In Example 5-1, it is formed in the main server 400 and measured by the measurement sensor 500. It includes an artificial intelligence server 440 that controls the relay server 300 according to information.

(Example 7-2) In Example 7-1, the equipment control system utilizing wireless communication for each module of the present invention is formed in the artificial intelligence server 440 and is used for controlling the equipment 100. A setting unit 441 that sets a reference value; A comparison unit 442 that compares the reference value set in the setting unit 441 with the measurement value measured by the measurement sensor 500; and a control unit 443 that controls each of the plurality of equipment devices 100 according to the information compared by the comparison unit 442.

(Example 7-3) In Example 7-1, the facility control system utilizing wireless communication for each module of the present invention is configured so that the setting unit 441 controls the location, season, and weather conditions of the facility device 100. It includes setting each reference value accordingly.

The present invention relates to the artificial intelligence server 440, and specifically, the artificial intelligence server 440 controls the equipment 100 by comparing the measurement value measured by the measurement sensor 500 with a preset reference value. This artificial intelligence server 440 is formed with a setting unit 441 that sets a reference value, and the setting unit 441 is configured according to the location, season, and weather conditions of the equipment 100 installed in each of the plurality of relay servers 300. Set the standard value. At this time, the reference value can be set differently for each of the plurality of relay servers 300, and the reference value can be set differently for each of the plurality of equipment 100 controlled by the relay server 300. This is to efficiently drive the equipment 100 by controlling each of the plurality of equipment 100. And the setting unit 441 sets reference values according to the location of the equipment 100, season, and weather conditions. To explain this in detail, in winter, when freezing occurs, current is supplied to the heating wire to prevent freezing of plumbing equipment, and in summer, when it rains a lot, the standard value of the water catch basin is set differently from other seasons to prevent rainwater from flowing back. In addition, according to the Korea Meteorological Administration, on days when cold waves or rainy seasons occur, the standard value is lowered to prepare for damage in advance. Additionally, the comparison unit 442 compares the set reference value with the measurement value measured by the measurement sensor 500. At this time, if the measured value exceeds the standard value, the control unit 443 transmits control information to a plurality of relay servers 300, and the control information is transmitted from the relay server 300 to the drive server ( 200) to be controlled.

In this way, damage can be prevented by analyzing and predicting risks in the artificial intelligence server 440 in the comparison unit 442 and effectively operating the equipment 100.

10: Building 100: Equipment
110: Temperature control device 120: Ventilation device
130: water level control device 200: driving server
210: wireless communication device 220: facility control device
300: relay server 310: first communication device
320: Second communication device 330: Relay control device
331: storage unit 332: conversion unit
400: Main server 410: Main communication department
420: Information storage unit 430: Auxiliary current supply unit
440: Artificial intelligence server 441: Setting section
442: comparison unit 443: control unit
500: Measurement sensor

Claims (10)

Equipment (100) installed in the building (10);
A driving server 200 formed in the equipment 100 and controlling the equipment 100;
A relay server (300) that communicates wirelessly with a plurality of the driving servers (200);
It includes a main server (400) that communicates wirelessly with a plurality of the relay servers (300),
The equipment 100 is,
A thermostat (110) that controls the temperature;
A ventilation device 120 that controls air quality inside the building 10; and
It includes a water level control device (130) that controls the water level in the basement of the building (10),
It includes an alarm device that warns when one of the air quality, temperature, humidity, and water level of the building 10 rises,
a first communication device 310 formed on the relay server 300 and communicating wirelessly with the driving server 200;
a second communication device (320) that communicates wirelessly with the main server (400);
It includes a relay control device 330 that controls the first communication device 310 and the second communication device 320,
The first communication device 310 and the second communication device 320 each use a short-range communication method selected from Wi-Fi, Zigbee, Bluetooth, and RF methods, and transmit and receive information through different types of short-range communication; Including,
A storage unit 331 formed in the relay control device 330 and storing information of the first communication device 310;
It is formed in the storage unit 331 and includes a conversion unit 332 that converts the short-distance communication method of the first communication device 310 to the short-range communication method of the second communication device 320,
The storage unit 331 stores the operating state of the equipment 100 and stores measurement information measured by the measurement sensor 500,
The first communication device 310 performs wireless communication using RF method using frequency, and the second communication device 320 performs wireless communication using Wi-Fi. In the first communication device 310, The received information is stored in the storage unit 331 of the relay server 300 and stored temporarily,
The main server 400,
A main communication unit 410 that communicates wirelessly with a plurality of the relay servers 300;
an information storage unit 420 formed in the main communication unit 410 and storing information received from a plurality of relay servers 300; and
It includes an auxiliary current supply unit 430 that supplies auxiliary power to maintain communication in the event of a power outage,
The information storage unit 420 stores the operating state of the equipment 100 and the measurement value measured by the measurement sensor 500. A facility control system using wireless communication for each module including.
In claim 1,
A facility control system using wireless communication for each module including a measurement sensor 500 formed in the building 10 and measuring one selected from air quality, water level, temperature, and humidity.
delete In claim 1,
a wireless communication device 210 formed on the driving server 200 and communicating wirelessly with the relay server 300;
A facility control system utilizing wireless communication for each module, including a facility control device (220) that controls the facility device (100) by the wireless communication device (210).
delete delete delete delete In claim 2,
An artificial intelligence server 440 formed in the main server 400 and controlling the relay server 300 according to information measured by the measurement sensor 500; facility control using wireless communication for each module including; system.
In claim 9,
A setting unit 441 formed in the artificial intelligence server 440 and setting a reference value for controlling the equipment 100;
A comparison unit 442 that compares the reference value set in the setting unit 441 with the measurement value measured by the measurement sensor 500;
A facility control system utilizing wireless communication for each module, including a control unit 443 that controls each of the plurality of equipment devices 100 according to the information compared by the comparison unit 442.