KR20190089658A - Central control apparatus for air conditioning facility - Google Patents

Abstract

The present invention relates to a central control apparatus for an air conditioning facility and, more specifically, to a central control apparatus for an air conditioning facility, which controls a plurality of air conditioning facilities to allow indoor air data to follow target air data. According to one embodiment of the present invention, the central control apparatus for a plurality of air conditioning facilities conditioning indoor air comprises: an air data collection unit collecting and cumulatively storing indoor air data in a database in real-time; an operation data collection unit collecting and cumulatively storing operation data of the air conditioning facilities in the database in real-time; a control data generation unit receiving target air data from a user and using the air and operation data cumulatively stored in the database to generate control data to allow the indoor air data to follow the target air data; and an air conditioning facility control unit controlling the air conditioning facilities based on the generated control data.

Description

[0001] CENTRAL CONTROL APPARATUS FOR AIR CONDITIONING FACILITY [0002]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a central control device for an air conditioner, and more particularly, to a central control device for an air conditioner that controls a plurality of air conditioners so that the air data of the room follows the target air data.

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

To this end, the central control device for the air conditioner is connected to a plurality of air conditioners through a network, and a plurality of air conditioners are installed in a specific space and perform respective functions under the control of the central control device for the air conditioner.

Conventionally, the central control device for air conditioning equipment adjusts the air by controlling the air conditioning equipment related to the parameter when it is necessary to improve any one parameter (for example, temperature, humidity, concentration, etc.) indicative of the state of the air.

In other words, the conventional central control device for air conditioning equipment harmonizes air using only the respective parameters without considering the various parameters (for example, temperature, humidity, concentration, etc.) indicating the state of the air as a whole.

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

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

That is, each of the parameters indicating the state of the air changes in real time according to the control operation for improving one of the parameters. According to the conventional control method, a plurality of parameters can not be comprehensively considered together, There is a problem that energy consumption occurs.

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

It is another object of the present invention to provide a central control device for an air conditioning system that accumulates and stores simulation data for controlling the state of indoor air, the operation state of an air conditioner, and indoor air.

The objects of the present invention are not limited to the above-mentioned objects, and other objects and advantages of the present invention which are not mentioned can be understood by the following description and more clearly understood by the embodiments of the present invention. It will also be readily apparent that the objects and advantages of the invention may be realized and attained by means of the instrumentalities and combinations particularly pointed out in the appended claims.

The present invention generates simulation data for causing indoor air data to follow the target air data, generates control data by comparing the generated simulation data and operation data, and transmits the generated control data to the air conditioning equipment, It is possible to control a plurality of air conditioning equipments so that the air data follows the target air data.

In addition, the present invention stores air data and operation data collected corresponding to a predetermined period so as to correspond to each other, and stores the simulation data corresponding to the air data on which the simulation data is generated, The operation state, and the simulation data for controlling the indoor air.

The present invention can control the plurality of air conditioning equipments so that the state of the room air follows the state of the air desired by the user, so that each air conditioning equipment can perform the efficient air conditioning function.

In addition, the present invention accumulates and stores simulation data for controlling the state of indoor air, the operation state of the air conditioner, and the indoor air so that the state change of the indoor air according to the control of the air conditioner is integrally managed and monitored .

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

The above and other objects, features, and advantages of the present invention will become more apparent by describing in detail exemplary embodiments thereof with reference to the attached drawings, which are not intended to limit the scope of the present invention. In the following description, well-known functions or constructions are not described in detail since they would obscure the invention in unnecessary detail. Hereinafter, preferred embodiments of the present invention will be described in detail with reference to the accompanying drawings. In the drawings, the same reference numerals are used to denote the same or similar elements.

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

1 is a view showing a state in which a central control unit for an air conditioning facility controls a plurality of air conditioning facilities through a network. FIG. 2 is a view showing a central control device for an air conditioning system according to an embodiment of the present invention, and FIG. 3 is a view illustrating a control flow for controlling the air conditioning system by the central control device for the air conditioning system shown in FIG. 2 . FIG. 4 is a view showing the detailed configuration of the air conditioner control unit shown in FIG. 2. FIG.

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

The central control unit 100 may be connected to a plurality of air conditioning units 10 through a network and a plurality of air conditioning units 10 may be installed in a room in a specific space, Each function can be performed according to the control.

The plurality of air conditioning equipments 10 may include various facilities for performing the air conditioning function. For example, as shown in FIG. 1, the air conditioning system 10 includes a cooling / heating facility including an outdoor unit 11 and an indoor unit 12, a ventilation facility 13 for forming an air flow path between indoor air and outdoor air A humidifying and dehumidifying facility 14 for raising or lowering the humidity of indoor air, and an air purifying facility 15 for purifying indoor air.

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

2, the central control apparatus 100 according to an embodiment of the present invention includes an air data collecting unit 110, an operation data collecting unit 120, a control data generating unit 130, an air conditioning equipment controller 140 And a database 150 (DB). The central control device 100 shown in FIG. 2 is according to one embodiment, and its components are not limited to the embodiment shown in FIG. 2, and some components may be added, changed or deleted have.

2 and 3, the air data collecting unit 110 collects indoor air data in real time and accumulates the collected air data in the database 150. FIG.

Here, the air data may include any information regarding the state of the room air. For example, the air data may include indoor air temperature information ^o C, humidity information (%), fine dust concentration (PM) information, chemical (e.g., CO ₂ ) .

The air data collecting unit 110 may collect the indoor air data according to a predetermined period set by the 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 system 10 may include a temperature sensor, a humidity sensor, a fine dust sensor, a chemical sensor, and the like.

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

For example, when the air data collecting unit 110 collects the air data every five minutes from 1:00 PM, the air data collecting unit 110 collects the air data such as 1:00, 1: 5, The collected air data can be stored according to the time at which the air is collected.

Accordingly, the acquisition time and the air data can be stored in the database 150 in association with each other.

Referring again to FIGS. 2 and 3, the operation data collection unit 120 may collect operation data of the plurality of air conditioning systems 10 in real time and accumulate them in the database 150. FIG.

Here, the operation data may include any information related to the operation state of the plurality of air conditioners 10. [ For example, the operation data includes ON / OFF information indicating a driving state of each air conditioner 10, a set temperature indicating a desired temperature of the indoor air, an operation mode of the air conditioner 10 (for example, A turbo mode, a tropical night mode, and the like), and a damper opening indicating the width of the flow path formed between indoor and outdoor.

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

For example, when the operation data collecting unit 120 collects the operation data every 10 minutes starting from 2:00 PM, the operation data collecting unit 120 collects the operation data such as 2:00, 2:10, 2:20, The operation data can be stored according to the time of collection.

Accordingly, the collection time and the operation data can be stored in the database 150 in association with each other.

As described above, the air data and the operation data are stored in the database 150, respectively. At this time, the air data and the operation data collected in a predetermined period may be stored in the database 150 so as to correspond to each other.

More specifically, the air data collecting unit 110 and the operation data collecting unit 120 may collect the air data and the operation data, respectively, in the same period based on the same time. The collected air data and the operation data are stored in the database 150, respectively, at which time the air data and the collected data can be stored so as to correspond to each other at the same collection time.

For example, when the air data collecting unit 110 and the operation data collecting unit 120 collect the air data and the operation data at intervals of 5 minutes based on 1:00 PM, the database 150 stores the air data and the operation data Can be stored in the form of a look-up table (LUT) as shown in Table 1 below.

Collection time Air data Operation data 1 o'clock Air data A Operation data A 1: 5 Air data B Operation data B 1:10 Air data C Operation data C

2 and 3, the control data generation unit 130 receives the target air data from the user, and uses the air data and the operation data accumulated in the database 150 to calculate the indoor air data as the target air data The control data can be generated.

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

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

More specifically, the control data generation unit 130 generates simulation data for controlling the air conditioning equipment 10 by comparing the accumulated air data with the target air data, compares the simulation data with the accumulated operation data, Lt; / RTI >

To this end, the control data generation unit 130 may include a plurality of modules shown in 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 generation unit 130 shown in FIG. 4 is according to an embodiment and its elements are not limited to the embodiment shown in FIG. 4, and some elements may be added, changed or deleted have.

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

The simulation module 142 may generate simulation data that causes the air data stored in the database 150 to follow the target air data input from the user.

The simulation program may be installed in advance in the simulation module 142, and information about each air conditioner 10, for example, facility performance, facility characteristics, facility efficiency, and the like may be stored in advance in the simulation program. In addition, information about the indoor space in which a plurality of air conditioning equipments 10 are installed, for example, facility installation position, the structure of the indoor space, and the like can be stored in advance in the simulation program.

The simulation module 142 can generate simulation data for causing the air data to follow the target data, based on the information about the air conditioning equipment 10 and the indoor space.

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

The variation of each air data according to the test data can be stored in the internal memory of the simulation module 142, respectively. In other words, in the simulation module 142, information on how each of the air data changes can be stored in advance when simulating (simulating) each facility through virtual operation data.

For example, if the temperature information contained in the current air data is 26 ^° C, the room temperature can be reduced from 26 ^° C to 22 ^° C by virtually controlling the cooling system by setting the test data to 22 ^° C . The simulation module 142 may store information on the amount of change of the room temperature over time under the virtual control condition in advance.

Also, when the temperature information included in the current air data is 26 ^° C, the room temperature can be reduced from 26 ^° C to 17 ^° C by virtually controlling the cooling system by setting the test data to 17 ^° C. The simulation module 142 may store information on the amount of change of the room temperature over time under the virtual control condition in advance.

That is, when the room temperature is 26 ^° C, the amount of temperature change with time for each test data can 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 minutes control 24 ^o C 22 ^o C 30 minutes control 23 ^o C 19 ^o C 40 minutes control 22 ^o C 17 ^o C

As described 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 determines that the current indoor air temperature (26 ^o C) ^o C test data 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 determines that the current indoor air temperature (26 ^o C) ^o C test data can be determined as simulation data.

Although the simulation module 142 has described examples of determining test data on temperature, the test data may include temperature information ^o C, humidity information (%), fine dust concentration (PM) information, For example, CO ₂ ) concentration information (ppm), and the like.

The simulation module 142 can perform the above-described simulation data determination operation on all the past air data accumulated in the database 150 as well as the air data of the current time.

The air data includes various parameters (temperature, humidity, concentration, etc.) regarding the state of the room air, and one of the parameters may affect other parameters.

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

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

As described above, the database 150 may store the operation data collected at the same time as the air data collected at a specific time to correspond to each other.

The data generation module 143 can generate the control data by comparing the simulation data, which is the virtual operation data, with the operation data corresponding to the air data on which the simulation data is generated.

The control data may be data that allows the operation data stored in the database 150 to follow the simulation data. Thus, each of the air-conditioning equipments 10 can receive the control data and change the operation data into the simulation data according to the control data.

For example, referring to Table 2, when the room temperature (air data) is 26 ^o C at the present time and the desired temperature (operation data) of the current cooling system is 24 ^o C, If the time is 20 minutes and the desired temperature is 22 ^° C, the simulation data can be determined at 17 ^° C.

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

The data generation module 143 can perform the above-described control data generation operation for all the past air data accumulated in the database 150 as well as the current time air data.

Meanwhile, the simulation module 142 may cumulatively store the simulation data in the database 150 so as to correspond to the air data on which the simulation data is generated.

As described above, the simulation module 142 can generate the simulation data for all the air data accumulated in the database 150. As the simulation data is stored in the database 150 so as to correspond to the respective air data, the air data and the simulation data can be stored in the database 150 in the form of a lookup table as shown in [Table 3] below.

Collection time Air data Simulation data 1 o'clock Air data A Simulation data A 1: 5 Air data B Simulation data B 1:10 Air data C Simulation data C

As described above, the present invention accumulates and stores simulated data for controlling the state of indoor air, the operation state of the air conditioner, and the indoor air so that the state change of the indoor air according to the control of the air conditioner is integrally managed And monitoring.

Accordingly, the control data generation unit 130 extracts simulation data corresponding to the air data collected in real time with reference to the database 150, and generates the control data based on the extracted simulation data and the operation data collected in real- Lt; / RTI >

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

The control data generation unit 130 can generate control data based on the extracted simulation data and the operation data at the control time point.

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

The air conditioning system control unit 140 can control a plurality of the air conditioning systems 10 based on the control data.

More specifically, the air-conditioning equipment control unit 140 may transmit 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 conditioner control unit 140 can exchange messages with each air conditioner 10 through asynchronous serial communication. More specifically, the air conditioning system controller 140 can communicate with the air conditioning system 10 through various serial communication protocols such as RS232, RS442, and RS485.

The air conditioning system 10 can receive the control data and change the operation data according to the control data so that the air data of the indoor air can be driven to follow the target air data desired by the user.

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

While the present invention has been described in connection with what is presently considered to be practical exemplary embodiments, it is to be understood that the invention is not limited to the disclosed embodiments, but, on the contrary, But the present invention is not limited thereto.

Claims (11)

A central control device for controlling a plurality of air conditioning equipments for harmonizing air in a room,
An air data collection unit for collecting air data of the room in real time and accumulating it in a database;
An operation data collecting unit for collecting operation data of the plurality of air conditioning equipments in real time and accumulating them in the database;
A control data generation unit that receives the target air data from the user and generates control data for causing the air data in the room to follow the target air data using the air data and the operation data accumulated in the database; And
And an air conditioning equipment controller for controlling the plurality of air conditioning equipment based on the generated control data
Central control unit for air conditioning equipment.
The method according to claim 1,
The plurality of air conditioning equipments
A central control device for an air conditioning system, comprising at least one of an air-conditioning and heating facility, a ventilation facility, an air-conditioning facility, a humidifying facility and a dehumidifying facility.
The method according to claim 1,
The air data
Wherein the central control unit includes at least one of temperature information, humidity information, fine dust concentration information, and chemical concentration information.
The method according to claim 1,
The operation data
And information on the operating state of the plurality of air conditioner equipments.
The method according to claim 1,
The air data collecting unit and the operation data collecting unit
Wherein the control unit collects the air data and the operation data of the indoor unit according to a predetermined period, and accumulates the collected air data and the operation data in the database according to the collection time.
6. The method of claim 5,
In the database,
Wherein the air data and the operation data collected in accordance with the predetermined period are stored so as to correspond to each other.
The method according to claim 1,
The control data generation unit
An input module for receiving the target air data from the user;
A simulation module for generating simulation data for causing the air data stored in the database to follow the target air data;
And a data generation module that generates the control data based on the simulation data and the operation data stored in the database
Central control unit for air conditioning equipment.
8. The method of claim 7,
The simulation module
Wherein the control data is variable-controlled to monitor the change of the air data, and the test data when the air data follows the target air data is determined as the simulation data.
8. The method of claim 7,
The data generation module
And generates control data for allowing the operation data stored in the database to follow the simulation data.
8. The method of claim 7,
The simulation module
And cumulatively storing the generated simulation data in the database so as to correspond to the air data on which the simulation data is generated.
11. The method of claim 10,
The control data generation unit
Extracts simulation data corresponding to the air data collected in real time by referring 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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