KR102423612B1 - Central control apparatus for air conditioning facility - Google Patents

Abstract

The present invention relates to a central control device for air conditioning equipment, and more particularly, to a central control device for air conditioning equipment that controls a plurality of air conditioning equipment so that indoor air data follows target air data. A central control device for air conditioning equipment according to an embodiment of the present invention is a central control device for controlling a plurality of air conditioning equipment for conditioning indoor air, wherein the indoor air data is collected in real time and accumulated in a database. An air data collection unit, an operation data collection unit that collects and stores operation data of the plurality of air conditioning facilities in real time in the database, receives target air data from a user, and accumulates and stores the air data and the operation data in the database A control data generator for generating control data for allowing the indoor air data to follow the target air data using characterized.

Description

CENTRAL CONTROL APPARATUS FOR AIR CONDITIONING FACILITY

The present invention relates to a central control device for air conditioning equipment, and more particularly, to a central control device for air conditioning equipment that controls a plurality of air conditioning equipment so that indoor air data follows target air data.

A central control device for an air conditioning facility is a device for controlling a plurality of air conditioning facilities.

To this end, the central control device for air conditioning equipment is connected to a plurality of air conditioning equipment through a network, and the plurality of air conditioning equipment is installed in a specific space to perform each function according to the control of the central control device for air conditioning equipment.

The conventional central control device for air conditioning equipment, when it is necessary to improve any one parameter (eg, temperature, humidity, concentration, etc.) indicating the state of the air, by controlling the air conditioning equipment related to the parameter to condition the air.

In other words, the conventional central control device for air conditioning equipment does not consider various parameters (eg, temperature, humidity, concentration, etc.) representing the state of the air as a whole, but uses only each parameter to condition the air.

For example, if the cooling of the indoor air is continued according to the conventional control method, the indoor carbon dioxide concentration may increase. When a damper is opened according to the conventional control method to lower the carbon dioxide concentration and external air is introduced, the indoor temperature may rise again and fine dust may be introduced.

In this case, additional cooling is required to lower the indoor temperature again, and an air cleaning operation is further required to remove fine dust.

That is, each parameter indicating the state of the air changes in real time according to a control operation for improving any one parameter. There is a problem in that energy consumption occurs.

An object of the present invention is to provide a central control device for air conditioning equipment that controls a plurality of air conditioning equipment so that the state of indoor air follows the state of air desired by a user.

Another object of the present invention is to provide a central control device for air conditioning equipment that accumulates and stores simulation data for controlling indoor air state, operating state of air conditioning equipment, and indoor air to correspond to each other.

The objects of the present invention are not limited to the above-mentioned objects, and other objects and advantages of the present invention not mentioned may be understood by the following description, and will be more clearly understood by the examples of the present invention. It will also be readily apparent that the objects and advantages of the present invention may be realized by the means and combinations thereof indicated in the claims.

The present invention generates simulation data for allowing indoor air data to follow target air data, generates control data by comparing the generated simulation data with operation data, and transmits the generated control data to air conditioning equipment, A plurality of air conditioning equipment may be controlled so that the air data tracks the target air data.

In addition, the present invention stores the air data and operation data collected according to a certain period to correspond to each other, and stores the simulation data to correspond to the air data that is the basis for generating the simulation data, so that the condition of indoor air and air conditioning equipment Simulation data for controlling the driving state and indoor air can be stored to correspond to each other.

According to the present invention, by controlling a plurality of air conditioners so that the state of indoor air follows the state of air desired by the user, each air conditioner can perform an efficient air conditioning function.

In addition, the present invention integrates management and monitoring of changes in the state of indoor air according to the control of the air conditioning equipment by accumulating and storing simulation data for controlling the indoor air state, the operating state of the air conditioning equipment, and the indoor air to correspond to each other. can

1 is a diagram illustrating a state in which a central control device for air conditioning equipment controls a plurality of air conditioning equipment through a network;
Figure 2 is a view showing a central control device for air conditioning equipment according to an embodiment of the present invention.
3 is a view showing a control flow for controlling the air conditioning equipment by the central control device for the air conditioning equipment shown in FIG. 2 .
4 is a view showing a detailed configuration of the air conditioning equipment control unit shown in FIG.

The above-described objects, features and advantages will be described below in detail with reference to the accompanying drawings, and accordingly, those skilled in the art to which the present invention pertains will be able to easily implement the technical idea of the present invention. In describing the present invention, if it is determined that a detailed description of a known technology related to the present invention may unnecessarily obscure the gist of the present invention, the detailed description will be omitted. Hereinafter, preferred embodiments according to the present invention will be described in detail with reference to the accompanying drawings. In the drawings, the same reference numerals are used to refer to the same or similar components.

Hereinafter, a central control device for air conditioning equipment according to an embodiment of the present invention will be described in detail with reference to FIGS. 1 to 4 .

1 is a diagram illustrating a state in which a central control device for air conditioning equipment controls a plurality of air conditioning equipment through a network. FIG. 2 is a diagram illustrating a central control device for air conditioning equipment according to an embodiment of the present invention, and FIG. 3 is a diagram illustrating a control flow in which the central control device for air conditioning equipment shown in FIG. 2 controls the air conditioning equipment. . In addition, FIG. 4 is a view showing a detailed configuration of the air conditioning equipment control unit shown in FIG. 2 .

Referring to FIG. 1 , a central control device for an air conditioning facility (hereinafter, referred to as a central control device 100 ) is a device for controlling a plurality of air conditioning facilities 10 for conditioning indoor air.

To this end, the central control apparatus 100 may be connected to a plurality of air conditioning equipment 10 through a network, and the plurality of air conditioning equipment 10 is installed inside a specific space to control the central control apparatus 100 . Each function can be performed according to the control.

The plurality of air conditioning equipment 10 may include various equipment performing an air conditioning function. For example, as shown in FIG. 1 , the air conditioning system 10 includes an air conditioning system including an outdoor unit 11 and an indoor unit 12 , and a ventilation system 13 that forms a flow path between indoor air and outdoor air. ), a humidification and dehumidification facility 14 for increasing or decreasing the humidity of the indoor air, and at least one of an air purification facility 15 for purifying indoor air.

Each of the air conditioning equipment 10 may be connected to the central control device 100 and a network. In addition, any one air conditioning equipment 10 may be connected to the other air conditioning equipment 10 and a network. To this end, the central control device 100 and each air conditioning equipment 10 may include a communication module.

Referring to FIG. 2 , the central control device 100 according to an embodiment of the present invention includes an air data collection unit 110 , a driving data collection unit 120 , a control data generation unit 130 , and an air conditioning facility control unit 140 . ) and a database (Data Base; DB, 150). The central control device 100 shown in FIG. 2 is according to an embodiment, and its components are not limited to the embodiment shown in FIG. 2 , and some components may be added, changed, or deleted as necessary. have.

2 and 3 , the air data collection unit 110 may collect and store indoor air data in real time in the database 150 .

Here, the air data may include any information about the condition of indoor air. For example, air data may include indoor air temperature information ( ^o C), humidity information (%), fine dust concentration (PM) information, chemical substance (eg, CO ₂ ) concentration information (ppm), etc. can

The air data collection unit 110 may collect indoor air data according to a predetermined period set by a user. In order to transmit air data to the air data collection unit 110 , the air conditioning equipment 10 may include various sensor modules. For example, the air conditioning equipment 10 may include a temperature sensor, a humidity sensor, a fine dust sensor, a chemical sensor, and the like.

The air data collection unit 110 may accumulate and store air data collected according to a predetermined period in the database 150 according to a collection time.

For example, when the air data collection unit 110 collects air data every 5 minutes from 1:00 pm, the air data collection unit 110 collects air data such as 1:00, 1:05, and 1:10. It is possible to store the collected air data according to the time it is collected.

Accordingly, in the database 150, the collection time and air data may be stored in correspondence with each other.

Referring back to FIGS. 2 and 3 , the operation data collection unit 120 may collect operation data of the plurality of air conditioning equipment 10 in real time and accumulate and store the operation data in the database 150 .

Here, the operation data may include arbitrary information regarding the operation state of the plurality of air conditioning facilities 10 . For example, the operation data includes ON/OFF information indicating the driving state of each air conditioning equipment 10 , a set temperature indicating a desired temperature of indoor air, and an operation mode (eg, power saving mode, turbo mode, tropical night mode, etc.) and a damper opening indicating the width of a flow path formed between indoors and outdoors.

The driving data collection unit 120 may collect driving data of the air conditioning equipment 10 according to a predetermined period set by a user, and may accumulate and store the collected driving data in the database 150 according to a collection time.

For example, when the driving data collection unit 120 collects driving data every 10 minutes from 2:00 pm, the driving data collection unit 120 collects driving data such as 2:00, 2:10, and 2:20. It is possible to store driving data according to the time at which the data is collected.

Accordingly, the collection time and driving data may be stored in the database 150 in correspondence with each other.

As described above, the air data and the driving data are respectively stored in the database 150, and in this case, the air data and the driving data collected according to a predetermined period may be stored in the database 150 to correspond to each other.

More specifically, the air data collection unit 110 and the driving data collection unit 120 may collect air data and driving data, respectively, according to the same period based on the same time. The collected air data and driving data are each stored in the database 150, and in this case, the air data and the collected data may be stored to correspond to each other at the same collection time.

For example, when the air data collection unit 110 and the driving data collection unit 120 collect air data and driving data at 5-minute intervals based on 1:00 pm, the database 150 contains air data and driving data. may be stored in the form of a look-up table (LUT) as shown in [Table 1] below.

collection time air data driving data 1 o'clock air data A driving data A 1:05 air data B driving data B 1:10 air data C driving data C

Referring back to FIGS. 2 and 3 , the control data generator 130 receives target air data from a user, and uses the air data and operation data accumulated and stored in the database 150 to convert the indoor air data into target air data. It is possible to generate control data to follow.

Here, the target air data is information about the indoor air condition desired by the user, and may correspond to the above-described air data. For example, when the information about the state of indoor air included in the air data has a temperature of 25 ^o C and a humidity of 60%, the information included in the target air data may be a temperature of 20 ^o C and a humidity of 40%.

In addition, the target air data may include a control time for changing the indoor air data to a state of indoor air desired by the user.

More specifically, the control data generator 130 compares the accumulated stored air data with the target air data to generate simulation data for controlling the air conditioning facility 10 , and compares the simulation data with the accumulated operation data to obtain control data. can create

To this end, the control data generator 130 may include a plurality of modules shown in FIG. 4 .

Referring to FIG. 4 , the control data generation unit 130 may include an input module 141 , a simulation module 142 , and a data generation module 143 . The control data generating unit 130 shown in FIG. 4 is according to an embodiment, and its components are not limited to the embodiment shown in FIG. 4 , and some components may be added, changed, or deleted as necessary. have.

The input module 141 may receive target air data from a user. More specifically, the input module 141 may receive target air data from a user through a user interface (UI) provided by the central control device 100 .

The simulation module 142 may generate simulation data such that the air data stored in the database 150 tracks the target air data input from the user.

A simulation program may be pre-installed in the simulation module 142 , and information on each air conditioning facility 10 , for example, facility performance, facility characteristics, facility efficiency, and the like, may be stored in the simulation program in advance. In addition, information on the indoor space in which the plurality of air conditioning facilities 10 are installed, for example, a facility installation location, a structure of the indoor space, etc. may be stored in the simulation program in advance.

The simulation module 142 may generate simulation data in which the air data follows the target data based on the above-described information on the respective air conditioning equipment 10 and the information on the indoor space.

More specifically, the simulation module 142 may variably control the test data to monitor changes in the air data, and determine the test data when the air data follows the target air data as the simulation data. Here, the test data may be virtual driving data.

A change amount of each air data according to the test data may be stored in the internal memory of the simulation module 142, respectively. In other words, information on how each air data changes when virtual control (simulation) of each facility is performed through virtual operation data may be stored in the simulation module 142 in advance.

For example, when the temperature information included in the current air data is 26 ^o C, if the test data is set to 22 ^o C to virtual control the air conditioning equipment, the indoor temperature can be reduced from 26 ^o C to 22 ^o C . In the simulation module 142 , information on the amount of time-dependent change of the indoor temperature in such a virtual control situation may be stored in advance.

In addition, when the temperature information included in the current air data is 26 ^o C, if the test data is set to 17 ^o C to virtually control the air conditioning equipment, the indoor temperature can be reduced from 26 ^o C to 17 ^o C. In the simulation module 142 , information on the amount of time-dependent change of the indoor temperature in such a virtual control situation may be stored in advance.

That is, when the room temperature is 26 ^o C, the amount of temperature change with time for each test data may be as shown in [Table 2] below.

Test data: 22 ^o C Test data: 17 ^o C 10-minute control 25 ^o C 24 ^o C 20 minute control 24 ^o C 22 ^o C 30 minute control 23 ^o C 19 ^o C 40 minutes control 22 ^o C 17 ^o C

As mentioned above, the target air data may include a control time.

In one example, if the control time included in the target air data is 40 minutes and the desired temperature is 22 ^o C, the simulation module 142 is configured so that the current indoor air temperature (26 ^o C) follows the desired temperature within 40 minutes. ^o The test data of C can be determined as simulation data.

In another example, if the control time included in the target air data is 20 minutes, and the desired temperature is 22 ^o C, the simulation module 142 may set the current indoor air temperature (26 ^o C) to follow the desired temperature within 20 minutes. ^o The test data of C can be determined as simulation data.

In the above, examples in which the simulation module 142 determines test data regarding temperature have been described, but the test data includes temperature information ( ^o C), humidity information (%), fine dust concentration (PM) information, chemical substances (eg, For example, CO ₂ ) concentration information (ppm) and the like may be determined, respectively.

The simulation module 142 may perform the above-described simulation data determination operation on all air data accumulated and stored in the database 150 in the past as well as air data at the current time point.

Air data includes various parameters (temperature, humidity, concentration, etc.) related to the condition of indoor air, and any one parameter may affect other parameters.

Accordingly, in order to determine the simulation data in consideration of each parameter, the simulation module 142 may use any analysis method of analyzing an output value through a plurality of parameters. For example, the simulation module 142 may generate the simulation data by an analysis method using a multi-linear regression (MLR) or an artificial neural network (ANN).

Referring back to FIG. 4 , the data generation module 143 may generate control data based on simulation data and driving data stored in the database 150 .

As described above, the database 150 may be stored so that the air data collected at a specific time and the driving data collected at the same time correspond to each other.

The data generation module 143 may generate control data by comparing simulation data that is virtual driving data and driving data corresponding to air data that is a basis for generating the simulation data.

The control data may be data that allows the driving data stored in the database 150 to follow the simulation data. Accordingly, each air conditioning facility 10 may receive control data, and may change operation data into simulation data according to the control data.

For example, referring back to [Table 2], when the indoor temperature (air data) is 26 ^o C at the current time and the desired temperature (operation data) of the current cooling facility is 24 ^o C, the control included in the target air data If the time is 20 minutes and the desired temperature is 22 ^° C, the simulation data can be determined to be 17 ^° C.

The data generation module 143 may generate control data for causing the desired temperature of the cooling facility currently set to 24 ^o C to follow 17 ^o C, that is, control data for lowering the desired temperature of the corresponding cooling facility by 6 ^o C. have.

The data generation module 143 may perform the above-described control data generation operation on all air data accumulated and stored in the database 150 in the past as well as air data of the current time point.

Meanwhile, the simulation module 142 may accumulate and store the simulation data in the database 150 so as to correspond to the air data that is the basis for generating the simulation data.

As described above, the simulation module 142 may generate simulation data for all air data accumulated and stored in the database 150 . As the simulation data is stored in the database 150 to correspond to each air data, the air data and the simulation data may be stored in the database 150 in the form of a look-up table as shown in [Table 3] below.

collection time air data simulation data 1 o'clock air data A Simulation data A 1:05 air data B Simulation data B 1:10 air data C simulation data C

As described above, the present invention integrates management of changes in indoor air conditions according to the control of air conditioning equipment by accumulating and storing simulation data for controlling indoor air conditions, operating conditions of air conditioning equipment, and indoor air to correspond to each other. and monitoring.

Accordingly, the control data generating unit 130 extracts simulation data corresponding to the air data collected in real time with reference to the database 150 , and control data based on the extracted simulation data and the driving data collected in real time can create

In other words, the control data generating unit 130 extracts simulation data pre-stored in the database 150 without generating simulation data again from the same air data after first generating the simulation data for the air data at a specific point in time. can do.

The control data generator 130 may generate control data based on the extracted simulation data and the driving data at the control time.

Since the process of generating control data using the simulation data has been described above, a detailed description thereof will be omitted herein.

The air conditioning equipment control unit 140 may control the plurality of air conditioning equipment 10 based on the control data.

More specifically, the air conditioning equipment control unit 140 transmits a message including control data to each air conditioning equipment 10 , so that the air conditioning equipment 10 operates according to the control data.

The air conditioning equipment control unit 140 may exchange messages with each air conditioning equipment 10 through asynchronous serial communication. More specifically, the air conditioning equipment control unit 140 may communicate with the air conditioning equipment 10 through various serial communication protocols such as RS232, RS442, RS485.

The air conditioning equipment 10 may be driven so that the indoor air air data follows the target air data desired by the user by receiving the control data and changing the operation data according to the control data.

As described above, according to the present invention, by controlling a plurality of air conditioning equipment so that the state of indoor air follows the state of air desired by the user, each air conditioning equipment can perform an efficient air conditioning function.

For those of ordinary skill in the art to which the present invention pertains, various substitutions, modifications and changes are possible within the scope of the present invention without departing from the technical spirit of the present invention. is not limited by

Claims (11)

A central control device for controlling a plurality of air conditioning equipment for conditioning indoor air, the central control device comprising:
an air data collection unit for collecting and storing the indoor air data in real time in a database;
a driving data collecting unit for collecting and accumulating operating data of the plurality of air conditioning facilities in real time in the database;
a control data generator for receiving target air data from a user and generating control data for allowing the indoor air data to follow the target air data by using the air data and the driving data accumulated and stored in the database; and
An air conditioning equipment control unit for controlling the plurality of air conditioning equipment based on the generated control data,
The air data collection unit and the driving data collection unit
Collecting the indoor air data and the driving data according to a predetermined period, respectively, and cumulatively storing the collected air data and the driving data in the database according to a collection time
Central control unit for air conditioning plants.
According to claim 1,
The plurality of air conditioning equipment is
A central control device for an air conditioning system comprising at least one of a heating and cooling system, a ventilation system, an air purification system, a humidification system, and a dehumidification system.
According to claim 1,
The air data
A central control device for air conditioning equipment including at least one of temperature information, humidity information, fine dust concentration information, and chemical substance concentration information.
According to claim 1,
The driving data is
A central control device for air conditioning equipment including information on operating states of the plurality of air conditioning equipment.
delete According to claim 1,
In the database
A central control device for air conditioning equipment for storing the air data and the operation data respectively collected according to the predetermined period to correspond to each other.
According to claim 1,
The control data generating unit
an input module for receiving the target air data from the user;
a simulation module for generating simulation data such that the air data stored in the database follows the target air data;
and a data generation module for generating the control data based on the simulation data and the driving data stored in the database.
Central control unit for air conditioning plants.
8. The method of claim 7,
The simulation module
A central control device for air conditioning equipment for variably controlling test data to monitor changes in the air data, and determining test data when the air data follows the target air data as the simulation data.
8. The method of claim 7,
The data generation module
A central control device for air conditioning equipment that generates control data such that the operation data stored in the database follows the simulation data.
8. The method of claim 7,
The simulation module
A central control device for air conditioning equipment for accumulating and storing the generated simulation data in the database so as to correspond to the air data used as a basis for generating the simulation data.
11. The method of claim 10,
The control data generating unit
A central control device for air conditioning equipment that extracts simulation data corresponding to the air data collected in real time with reference to the database, and generates the control data based on the extracted simulation data and the operation data collected in real time.

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