KR100955210B1 - The intelligent style building control system for the most management and an energy curtailment of business building equipment and control method - Google Patents

Abstract

PURPOSE: An intelligent building system and a control method thereof are provided to optically operate an air conditioning facility by predicting an environmental requirement level of an occupant at each room in the building after measuring environmental information in real time. CONSTITUTION: A monitoring unit periodically measures a temperature and humidity inside and outside a building(S1). An average value of the measured temperature and humidity is calculated(S2). The calculated average value is stored in a database(S3). Data before obtaining the average value is deleted(S4). An air conditioning satisfaction survey server receives the air conditioning satisfaction survey value from a PC of a user, which is connected to an internet connection unit(S5). A total of the air conditioning survey value of the user is calculated(S6). A search studying process of the temperature and humidity suitable for each situation is performed using the total data of the selection values of the user and the average value of the temperature and humidity(S8). An air conditioning controller controls an air conditioning system according to the studying data(S9).

Description

The intelligent style building control system for the most management and an energy curtailment of business building equipment and control method}

The present invention relates to an intelligent building control system for optimal management and energy saving of office building equipment, in particular, to predict the environmental requirements of the occupants for each room in the building to perform the optimal operation of the air conditioning equipment according to the requirements of the occupants The present invention relates to an intelligent building control system and control method for optimal management and energy saving of office building equipment.

Air Conditioning refers to keeping the air temperature, humidity, air flow, and cleanness in a state suitable for indoor use. In modern society, it is common to live in a confined space within a limited space of various buildings such as office buildings, apartment buildings, and condominiums in urban areas. In order to improve, it is required to keep the temperature and humidity and cleanness of indoor air in an appropriate state at all times.

The air conditioning method of the building is based on installing an air conditioner in the machine room and supplying the air harmonized by the air conditioner to each room through the duct.It can be divided into the central method and the individual method based on the air distribution method. Among them, the central method produces heat medium from the heat source equipment installed in the central machine room and supplies it to the air conditioner installed on the secondary side, thereby supplying the harmonized air to each room or zone. The central air conditioning system can be classified into an all air system, an air-water system, and an all water system according to the type of heat medium used.

Conventionally, the central air conditioning system of a building may be divided into a constant air flow method and a variable air flow method according to which of the temperature or air flow amount of the air supplied to each room is changed to match the load variation of the room. Among these, the constant air flow method is a method of coping with load fluctuations by changing the air blowing temperature while maintaining a constant air flow rate, and the Variable Air Volume System (VAV: Variable Air Volume System) keeps the air blow temperature constant and changes according to load fluctuations. The room temperature is controlled by changing the air volume. In the place where the load fluctuation is small indoors, the variable air volume method which maintains a constant air supply temperature is mainly adopted, and in the place where the load fluctuation range is large, the constant air volume method which changes a supply air temperature is mainly adopted.

In the conventional building automatic control system, the control is performed based on physical conditions such as indoor temperature, humidity, wind speed, and the like, thereby controlling energy exceeding the requirements of the occupants. For example, with respect to physical conditions such as the same room temperature, humidity, and wind speed, humans may experience different comforts depending on the day of wear, the sharing of space with other occupants in the office, and even the days of the week including holidays. The HVAC system is wasting energy by doing the same, despite these factors.

On the other hand, the conventional air conditioning system is composed of various sensors for measuring temperature, humidity, pressure, wind speed, etc., various actuators such as damper controls, valve controls, dampers, valves, and the like. It is an international standard of communication method and adopts BACnet (Building Automation & Control Network), which is Korea's KSC6909 standard, as a communication protocol, and forms a network with all the controllers and field devices that make up the automatic control system. The occupant's PC is connected to the Internet using the TCP / IP communication protocol, which makes it difficult to control the comfort of the occupant.

The present invention has been made in order to solve such a conventional problem, and collects and organizes the operation information for each facility in the building and various real-time environmental information inside and outside the building, and the environmental requirement level of the occupants for each room in the building. The purpose of this study is to provide an intelligent building control system and control method for optimal management and energy saving of office building equipment that can perform the optimal operation of the air conditioning equipment according to the requirements of the occupants.

The present invention for achieving the above object is the air supply duct having a plurality of air supply guide ducts branched into each of the division space, each compartment of the building living; A ventilation duct installed separately from the air supply duct in the division space and having a plurality of ventilation guide ducts branched into each division space; It is installed between the outside air inlet side and the indoor side of the air supply duct, a heat exchanger for heat exchange by contacting the intake air introduced from the outside with the heat medium or the refrigerant body and a blower for passing the air passing through the heat exchanger to the indoor side of the air supply duct Air conditioning unit having; A damper installed on the air supply duct of the air supply duct to adjust the opening degree of the duct, a damper actuator for driving the damper, and each of the divisions by controlling the driving of the damper actuator installed in the respective spaces. A zone air volume control unit having a wind volume controller for controlling the air volume introduced into the space; A monitoring unit installed in each of the divided spaces and measuring a current temperature and humidity of the room and transmitting the measured air volume to the airflow controller; A direct digital controller which receives temperature and humidity data from a monitoring unit installed on the air supply duct and the ventilation duct and controls the wind speed and the air volume of the air supply duct and the ventilation duct; And connected to the direct digital controller and the air volume controller by a line capable of two-way communication, and collectively receive and collect information collected by the direct digital controller, and control subordinate to the direct digital controller. A central control unit for controlling an object and monitoring a processing state of the air flow controller and changing a set value; PCs used by occupants installed in each space; An air conditioning satisfaction survey server networked with the occupant using PC; A protocol conversion module connected to the central control unit and converting a protocol of the air conditioning satisfaction survey server into a protocol of a building control system; It characterized in that it comprises a database for storing the temperature and humidity information, air conditioning satisfaction information.

Meanwhile, the air conditioning satisfaction survey server examines the air conditioning satisfaction of the occupants on a unit of time basis, that is, on a daily basis or in a time unit, and then, after learning the air conditioning satisfaction of each occupant, determines whether the occupants are occupied based on the logon state of the occupant's personal computer. By setting the set value of the air conditioning state of the room belonging to the room.

On the other hand, the present invention method for achieving the above object, the step of measuring the temperature and humidity of the monitoring unit outside and inside the building at regular time intervals (S1); Calculating an average value of temperature and humidity values measured at the predetermined time intervals (S2); Transmitting and storing the calculated average value to a database (S3); Deleting the data before the point in time after obtaining the average value (S4); Receiving, by the air conditioning satisfaction survey server, the air conditioning satisfaction value input from the user's PC connected to the Internet connection unit (S5); Calculating a total of the air conditioning satisfaction values of the received user (S6); Repeating from step S2 to step S6 after the time point at which the sum of the average value and the selection value is obtained (S7); Learning to find a temperature and humidity suitable for each situation by using the average value of the temperature and humidity and the sum data of the user's selection value (S8); Controlling, by the air conditioning control device, an air conditioning system using the learning data (S9); Characterized in that consists of.

On the other hand, the step of learning to find the temperature and humidity for each situation using the average value of the temperature and humidity, and the average value data for the user's selection value (S8) according to the air conditioning satisfaction value selected by the user Adjusting (S81); Storing an external temperature and humidity, a building internal temperature, and a humidity value at that time when a selection value indicating satisfaction among user selection values is 80% or more (S82); When the data values are the same, when the satisfaction level is higher than step S82, the data value is stored and the previously stored data value is deleted (S83).

As described above, according to the present invention, unlike the conventional air conditioning system control that controls the room temperature to match a certain set value regardless of the conditions of the surrounding environment, the user is asked about the environment and the user's air conditioning satisfaction, By controlling the temperature and humidity according to the air conditioning satisfaction selected by the user, it is effective to control the air conditioning system in terms of comfort, not simply a matter of temperature and humidity, and the input air conditioning satisfaction survey data and the corresponding temperature and humidity Learning and operating the data has the effect of saving energy.

In addition, in measuring and acquiring data for the control of the air conditioning system, the average value is used to obtain the average value and then the data used to obtain the average value is deleted to reduce the capacity of the database and increase the processing speed. have.

In addition, it is connected to the user's PC through the Internet, and by using the Web to log in to the program has the effect that the administrator can remotely control and manage the air conditioning system where the Internet is connected.

Hereinafter, preferred embodiments of the present invention will be described in detail with reference to the accompanying drawings.

1 is a schematic configuration diagram of an air conditioning system of an intelligent building control system for optimal management and energy saving of the inventors' office building equipment, and FIG. 2 is an intelligent building control system and surroundings for optimal management and energy saving of the inventor's office building equipment. 3 is a block diagram illustrating an internal configuration of the airflow regulator.

According to the present invention, there is provided an air supply duct 30 having a division space where each occupant of a building resides, and a plurality of air supply guide ducts 35 branched into each division space; A ventilation duct 40 installed separately from the air supply duct 30 in the division space and having a plurality of ventilation guide ducts 45 branched into each division space; It is installed between the outside air inlet side and the indoor side of the air supply duct 30, and passes through the heat exchanger 11 and the heat exchanger 11 for heat exchange by contacting the intake air introduced from the outside with the heat medium or the refrigerant body. An air conditioner (10) having a blower (18) for sending air to the indoor side of the air supply duct (30); The damper 510 is installed on the air supply duct 35 of the air supply duct 30 to adjust the opening degree of the duct, the damper actuator 530 to drive the damper 510, and the respective divisions. A zone-specific wind volume control unit installed in the space and having a wind volume controller 500 for controlling the amount of air flowing into the respective divided spaces by controlling the driving of the damper actuator 530; A monitoring unit 520 installed in each division space and measuring current temperature and humidity of the room and transmitting the measured air volume controller 500 to the air flow controller 500; Direct digital controller which receives temperature and pressure data from the temperature sensor and the pressure sensor installed on the air supply duct 30 and the ventilation duct 40 and controls the wind speed and the air volume of the air supply duct 30 and the ventilation duct 40. 61; And connected to the direct digital controller 61 and the air volume controller 500 by a line capable of two-way communication, and collectively receive and collect information collected by the direct digital controller 61 and the direct digital controller ( A central control unit 60 for controlling a control target according to the control command by giving a control command to the control unit 61 and monitoring a processing state of the air volume controller 500 and changing a set value; Occupant using PC 70 installed in each division space; An air conditioning satisfaction survey server 80 forming a network with the occupant using PC 70; A protocol conversion module 90 connected to the central control unit 60 to convert the protocol of the air conditioning satisfaction survey server 80 into a protocol of the building control system; It includes a database 100 for storing the temperature and humidity information, air conditioning satisfaction information.

On the other hand, the air volume control section for each zone to control the supply air volume of each room of the building is installed on the air supply guide duct 35 of the air supply duct 30, the damper 510 for adjusting the opening degree of the duct, the damper Damper actuator 530 for driving the air volume, and a variable air volume controller (V-ZCU: Zone for Variable Air Volume) is installed in each room of the building and controls the amount of air flowing into each room by controlling the driving of the damper actuator 530 Control Unit; 500).

First, the air flow regulator 500 is installed at a height (approximately 1 m 20 cm from the ground) that is easily accessible by the occupant to the walls of each room of the building, and the damper actuator 530 is installed adjacent to the damper 510. The air flow rate sensor 540 is separately provided immediately before the damper 510.

2 and 3, the air volume controller 500 may input the set temperature and the set air volume through the key input unit 502, and the set temperature and the set air volume are thus stored in the memory 509. . The air flow regulator 500 is connected to the monitoring unit 520 installed at a proper position of each room, and compares the current room temperature and the air volume transmitted from them with the set temperature and the set air volume stored in the memory 509, and the necessary calculation process. By outputting the control signal to the damper actuator 530.

In FIG. 1, the air volume controller 500 is not directly connected to the digital controller 61, but is directly connected to the central controller 60 by a separate communication line 700.

The air flow controller 500 of the present invention includes a function of a controller built in a conventional air flow unit, and additionally, the air flow controller 500 further includes the same arithmetic and communication functions as the digital controller 61. Directly communicating with the central control unit 60 without the intervention of the digital controller 61, all information such as the set temperature, the set air volume, the current temperature, the current air volume, the damper opening degree and the like are shared.

On the other hand, the occupant using PC (70) refers to a computer used by the occupant in the office space, a program that is connected via the Internet and receives a question from the air conditioning satisfaction survey server 80, and select the answer It is installed.

The air conditioning satisfaction survey server 80 forms a network with the occupant using PC 70 and transmits a question to select the air conditioning satisfaction to the occupant using PC 70 through the Internet. By transmitting the question, the user can input the degree of comfort felt in the building through the occupant use PC 70 and transmit the input selection information to the database 100. For example, if the user inputs information such as cold, hot, satisfied, wet, and dry, and sends it to the user, the user selects his or her air conditioning satisfaction and collects the selected information and collects the database ( 100). This is to identify the user's comfort level according to the user's wear or activity, the external temperature and humidity in the same temperature and humidity environment.

On the other hand, using the data transmitted to the database 100, the air conditioning satisfaction survey server 80 can learn, and if the same situation in the future, the air conditioning satisfaction by allowing the automatic control even without sending the air conditioning satisfaction survey questions This saves the energy of running the air conditioning system because it saves questions to increase and consequently the air conditioning system control time.

The protocol conversion module 90 connects the air conditioning satisfaction survey server 80 with the central control unit 60 to control the air conditioning system according to the air conditioning satisfaction. The air conditioning satisfaction survey server 80 is based on TCP / IP. It is connected to the Internet, and the central control unit 60 and the air conditioning system adopt BACnet (BACnet: Building Automation & Control Network), which is a standard standard (KSC6909), as a communication protocol. Because the network and the network are configured, the control protocol is to connect different things to each other. That is, the air conditioning system can be controlled by controlling the central control unit 60 through the Internet-based PC 70 and the air conditioning satisfaction survey server 80 having different connection protocols.

Unlike the uniform temperature and humidity control by this configuration, it is possible to change the temperature and humidity according to the user's air-conditioning satisfaction to increase the satisfaction of the occupants, and to save and learn the information when the occupancy satisfaction is high This can be used for automatic control in the future to save energy.

Referring to FIG. 3, the air flow regulator 500 of the present invention receives an AC or DC power supply unit 501 for converting into a predetermined DC power, a key for inputting a command such as temperature setting and display state change. The input unit 502, the built-in indoor temperature sensor 504a for measuring the current temperature of the room and outputting it as an electric signal, the built-in indoor temperature sensor 504a and the monitoring unit 520 are connected in parallel and one of Only a signal is selectively input, and the temperature and air volume input unit 504, which receives the current air volume value from the air volume sensor 540, the set temperature value received from the key input unit 502 and from the temperature and air volume input unit 504 The central processing unit 508 for outputting a damper driving signal to the damper actuator 530 by comparing and calculating the received current indoor temperature and air volume, and the set temperature value, the set air volume value, and the like referenced by the central processing unit 508. I / O is connected to a memory 509 for storing other necessary information, a display unit 505 for displaying a current temperature, a set temperature and an operation state, and a portable operation terminal 506 such as a portable working terminal and a laptop computer. It is composed of an external terminal signal input unit 506 capable of processing, and a Dip Switch input unit 507 for setting a unique number or address of the air flow controller 500. At this time, the display unit 505 is composed of a FND display unit 505a and an LED display unit 505b. The FND display unit 505a displays numbers and simple messages such as temperature and air volume, and the LED display unit 505b is powered on. On / Off, abnormal alarm, etc. are displayed.

On the other hand, the built-in indoor temperature detection unit 504a of the two room temperature detection unit connected in parallel to the temperature and air flow input unit 504 is configured as a dummyistor (Thermistor) is installed in the air flow regulator 500, monitoring The unit 520 is constructed using platinum resistance thermometer (PT1000) and is installed at an appropriate position of the indoor wall. The temperature and air volume input unit 504 is basically set to preferentially receive the temperature data sent from the monitoring unit 520, and if omitted because it is not a place to install the monitoring unit 520, the built-in indoor temperature detection unit ( 504a) receives the temperature data and performs a proportional control process.

The central processing unit 508 in the air volume controller 500 receives input data from the key input unit 502 and the temperature and air volume input unit 504, and outputs a display control signal to the display unit 505. 508a) and, when the key input received from the input / output interface unit 508a is a set temperature value, stores it in the memory 509 and compares the result with the current temperature and the current air volume received from the input / output interface unit 508a. An operation control unit 508b for outputting the proportional control signal, and a control signal output unit 508c for converting the control signal received from the operation control unit 508b into a control signal for driving the damper actuator.

Intelligent building control system for optimal management and energy saving of office building equipment according to the present invention is primarily to adjust the opening degree of the damper 510 for the control of the indoor temperature, but at the same time fan coil unit (FCU :) When the fan coil unit 550 is installed, the control signal output unit 508c may further generate a control signal for driving the fan coil unit.

In addition, the air flow regulator 500 of the intelligent building control system for optimal management and energy saving of office building equipment according to the present invention is provided with an emergency switch (not shown), such as toggle switch, slide switch, air flow regulator Even when the 500 is in an operating error state, it is possible for the occupant to manually adjust the opening degree of the damper 510 by operating the emergency switch. For example, if the output is 10V when the slide switch is ON and the output is 0V, the damper is fully open at 10V output, and the damper is all at 0V output. If the output is between 0-10V, the damper can be opened in proportion to it.

Referring to FIG. 2, the sensor unit 541 detects the air volume of the air supply guide duct 35, and a converter 542 converts the physical quantity measured by the sensor unit 541 into an electrical signal and outputs the electrical signal. When the hot air flow rate sensor 540 is exposed to the flow of gas in a state in which the heating wire 541a of the sensor unit 541 is heated, the hot air flow rate sensor 540 measures the air flow rate by the degree of cooling of the heating wire 541a by the gas or the amount of heat absorption of the gas. That's the way it is.

4 is a flowchart illustrating a control method sequence of an intelligent building control system for optimal management and energy saving of an office building facility according to an embodiment of the present invention.

As shown in the drawings, the method of the present invention provides a method for achieving the above object, the monitoring unit measuring the temperature and humidity of the building exterior and interior at regular intervals (S1); Calculating an average value of temperature and humidity values measured at the predetermined time intervals (S2); Transmitting and storing the calculated average value to a database (S3); Deleting the data before the point in time after obtaining the average value (S4); Receiving, by the air conditioning satisfaction survey server, the air conditioning satisfaction value input from the user's PC connected to the Internet connection unit (S5); Calculating a total of the air conditioning satisfaction values of the received user (S6); Repeating from step S2 to step S6 after the time point at which the sum of the average value and the selection value is obtained (S7); Learning to find a temperature and humidity suitable for each situation by using the average value of the temperature and humidity and the sum data of the user's selection value (S8); Controlling, by the air conditioning control device, an air conditioning system using the learning data (S9); Characterized in that consists of.

The step S1 of the monitoring unit measuring the temperature and humidity of the exterior and the interior of the building at regular time intervals is a step of measuring the current temperature and humidity in order to warm the temperature to control the temperature and humidity of the air conditioning system. The reason for measuring the temperature and humidity of the outside of the building is that the comfort of the interior of the building varies depending on the outside temperature and humidity, so that the temperature and humidity of the building can be adjusted by reflecting this.

In calculating the average value of the temperature and humidity values measured at regular time intervals (S2), the temperature and humidity are measured at regular time intervals in measuring the temperature and humidity, and at a predetermined time interval, the time interval is measured. It is a step of calculating the average of the temperature value and the humidity value. Temperature and humidity measurements can be controlled more precisely with smaller time intervals. However, the smaller the measurement interval, the more data is accumulated and the larger the storage space, and a higher performance processor is required to process the data. Therefore, the data is measured at a small measurement interval, and the average value of the measured data values is calculated to increase the accuracy of the data.

Determining the average value and then deleting the data before the time point for obtaining the average value (S4) is a step of deleting the measured values of temperature and humidity used to obtain the average value. By using the measured value to calculate the average value, leaving only the calculated average value and deleting the remaining measured value can not burden the capacity of the database, and does not burden the air conditioning control.

The air conditioning satisfaction survey server receives the air conditioning satisfaction value input from the user's PC connected to the Internet connection (S5) to select the current state that the user feels in a situation where the air conditioning system is adjusting the temperature and humidity. In other words, the current user's situation can be selected from among views such as hot, wet, dry, good, satisfied, and the like, so that the information by the user's selection is stored in the database.

Computing a total of the received air conditioning satisfaction value (S6) is a step of calculating the selected total of each view selected in the step S5. By calculating the total, it can be reflected in the temperature and humidity control according to the selected view, so that it can have the best comfort according to the external environment and the user's condition.

Learning to find the temperature and humidity for each situation using the average value of the temperature and humidity, and the average value data for the user's selection value (S8) is the step of adjusting the temperature and humidity according to the user selected selection value (S81); Storing an external temperature and humidity, a building internal temperature, and a humidity value at the time when the selection value indicating satisfaction of the user selection value is 80% or more (S82); When the data values are the same, when the satisfaction level is higher than step S82, the data values are stored and the previously stored data values are deleted (S83).

In the step S9 of controlling the air conditioning system by the air conditioning control device using the learning data, when the ratio of satisfaction is 80% or more, the temperature and humidity are adjusted by selecting the total sum of satisfaction selected by the user in the room. If the satisfaction is less than 80%, the satisfaction survey is conducted continuously for a certain time unit (for example, 10 minutes, 30 minutes, 1 hour) so that the user's air conditioning satisfaction can increase.

Referring to the operation and effect of the present invention made of such a configuration and steps as follows.

First, outdoor temperature and humidity, indoor temperature and humidity are measured through a monitoring unit, and the measured values are stored in a database. Shorter time intervals can be used to quickly respond to changes in temperature.

Meanwhile, the air conditioning satisfaction survey server transmits the air conditioning satisfaction survey question to a PC used by an in-patient who is connected to the Internet, and selects one of the contents in the question. For example, it can be cold, hot, satisfied, warm, and can be adjusted to fit the building's situation.

Through the questions as described above, it is possible to select a user's comfort and analyze the data to generate control information for controlling the air conditioner. The generated control information is converted into a protocol used in the network of the air conditioning system through the protocol conversion module and transmitted to the central controller. The central controller receiving the control signal sends a control signal to the digital controller to control the entire air conditioning system. Make sure you have the desired temperature and humidity.

This is because the user's comfort is changed by external factors even under the same temperature and humidity, so that the user's comfort is not reflected by controlling the air conditioning system by simply maintaining the set temperature and humidity.

For the air conditioning system to have the best comfort control, it is necessary to remember the accumulation of continuous data and temperature and humidity according to external factors so that the next learned control can be applied the next time it encounters an environment with similar external factors. To ensure that Learning becomes more applicable when there is a lot of data and the environment experienced by the controller increases.

That is, by collecting the average of the measured data, the amount of data can be reduced in collecting the data for learning, and the user can optimize the comfort of the user depending on external factors through learning. It is to be able to work in the environment.

Although the above-described embodiments have been described with respect to the most preferred embodiments of the present invention, it is not limited to the above embodiments, and it will be apparent to those skilled in the art that various modifications can be made without departing from the technical spirit of the present invention.

1 is a schematic configuration diagram of an air conditioning system of an intelligent building control system for optimal management and energy saving of the present inventors office building equipment,

FIG. 2 is a diagram illustrating a connection state between an intelligent building control system and surrounding external devices for optimal management and energy saving of the office building equipment of the present inventors; FIG.

3 is an internal block diagram of the air flow regulator;

Figure 4 is a flow chart showing the operation of the control method of the intelligent building control system for optimal management and energy saving of the office building equipment which is an embodiment of the present invention.

Explanation of symbols on the main parts of the drawings

10: air conditioning unit 11: heat exchanger

18: blower 30: air supply duct

35: duct 40: ventilation duct

45: ventilation guide duct 60: central control unit

61: direct digital controller 70: personal computer

80: air conditioning satisfaction survey server 90: protocol conversion module

100: database 500: air flow regulator

501: power supply unit 502: key input unit

504: air flow input unit 504a: built-in room temperature detection unit

505: display portion 505a: FND display portion

505b: LED display unit 506: external terminal signal input unit

507: dip switch input unit 508: central processing unit

509: memory 510: damper

520: monitoring unit 530: damper actuator

540: hot air flow rate sensor 541: sensor unit

541a: heating wire 700: air conditioning system communication line

800: internet communication line

Claims (4)

delete An air supply duct having a division space in which each occupant of the building resides, and a plurality of air supply guide ducts branched into each division space; A ventilation duct installed separately from the air supply duct in the division space and having a plurality of ventilation guide ducts branched into each division space; It is installed between the outside air inlet side and the indoor side of the air supply duct, a heat exchanger for heat exchange by contacting the intake air introduced from the outside with the heat medium or the refrigerant body and a blower for passing the air passing through the heat exchanger to the indoor side of the air supply duct Air conditioning unit having; A damper installed on the air supply duct of the air supply duct to adjust the opening degree of the duct, a damper actuator for driving the damper, and each of the divisions by controlling the driving of the damper actuator installed in the respective spaces. A zone air volume control unit having a wind volume controller for controlling the air volume introduced into the space; A monitoring unit installed in each of the divided spaces and measuring a current temperature and humidity of the room and transmitting the measured air volume to the airflow controller; A direct digital controller which receives temperature and humidity data from a monitoring unit installed on the air supply duct and the ventilation duct and controls the wind speed and the air volume of the air supply duct and the ventilation duct; And connected to the direct digital controller and the air volume controller by a line capable of two-way communication, and collectively receive and collect information collected by the direct digital controller, and control subordinate to the direct digital controller. A central control unit for controlling an object and monitoring a processing state of the air flow controller and changing a set value; PCs used by occupants installed in each space; After establishing a network with the occupant using PC and researching the air-conditioning satisfaction of the in-patients on a unit of time basis, that is, on a daily basis or in a unit of time, learning the air-conditioning satisfaction of each occupant and determining whether the occupants are occupied based on the logon state of the in-home personal computer. An air conditioning satisfaction survey server for setting a set value of an air conditioning state of a room to which the corresponding occupants belong; A protocol conversion module connected to the central control unit and converting a protocol of the air conditioning satisfaction survey server into a protocol of a building control system; Intelligent building control system for optimal management and energy saving of office building equipment, including a database for storing temperature, humidity information and air conditioning satisfaction information. The monitoring unit measures the temperature and humidity of the outside and inside the building at regular time intervals (S1); Calculating an average value of temperature and humidity values measured at the predetermined time intervals (S2); Transmitting and storing the calculated average value to a database (S3); Deleting the data before the point in time after obtaining the average value (S4); Receiving, by the air conditioning satisfaction survey server, the air conditioning satisfaction value input from the user's PC connected to the Internet connection unit (S5); Calculating a total of the air conditioning satisfaction values of the received user (S6); Repeating from step S2 to step S6 after the time point at which the sum of the average value and the selection value is obtained (S7); Learning to find a temperature and humidity suitable for each situation by using the average value of the temperature and humidity and the sum data of the user's selection value (S8); Controlling, by the air conditioning control device, an air conditioning system using the learning data (S9); Intelligent building control system control method for optimal management and energy saving of office building equipment, characterized in that consisting of The method of claim 3, wherein Learning to find the temperature and humidity for each situation by using the average value of the temperature and humidity, and the average value data for the user's selection (S8) is to adjust the temperature and humidity according to the air conditioning satisfaction value selected by the user Step S81; Storing an external temperature and humidity, a building internal temperature, and a humidity value at that time when a selection value indicating satisfaction among user selection values is 80% or more (S82); If the data value is the same, when the satisfaction level is higher than step S82, storing the data value and deleting the previously stored data value (S83); Optimal management and energy of the office building equipment, characterized in that consisting of Intelligent building control system control method for saving,

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