KR102091639B1 - Automatic building control system and control method thereof - Google Patents

Abstract

The present invention relates to a building automatic control system in which a building energy management system (BEMS) for reducing energy consumed in building is built. More specifically, provided are the building automatic control system capable of automatically operating without intervention of a manager by controlling driving of an installation device by automatically determining which control command to execute, when a general control command of the building automatic control system itself and a BEMS control command of the BEMS collide for a specific facility, and the control method thereof.

Description

Automatic building control system and control method thereof

The present invention relates to a building automatic control system with a built-in building energy management system (BEMS, Building Energy Management System) for reducing energy consumed in a building, and more specifically, for a specific facility, the building automatic control system itself When the general control command and BEMS control command of the building energy management system collide, it automatically determines which control command is to be executed and controls the operation of the facility, so that the building automatic control system and its control method can be operated automatically without administrator intervention. It is about.

In general, it is known that energy used in buildings accounts for 30-40% of the total energy consumption.

Accordingly, various attempts have been made to reduce energy used in buildings, and energy saving attempts have been made using Building Energy Management System (BEMS) and Building Automation System (BAS).

Building Automation System (BAS) performs most of functions (EMS, Energy Management System) to increase control, management, and energy use efficiency for various facilities in the building. The main energy-using facilities are air conditioning / heating facilities, air conditioning facilities, ventilation facilities, sanitary facilities, pumps, lighting, etc. The automatic building control system automatically controls facilities with control algorithms optimized for the control of various facilities.

These facility control algorithms are created by a professional engineer during field commissioning using software provided by the system supplier, and the software for control logic creation is various methods such as ladder, function block diagram (FBD) method, and dedicated script language. It is provided with FBD type control logic writing software.

On the other hand, until now, the Building Energy Management System (BEMS) provides users with analysis information on energy consumption and energy efficiency without performing algorithms for energy saving at the system level directly through the target facility. A method is selected so that optimum control for energy saving is performed by the user. These BEMS functions and operating methods can only be performed by experts who are high-level technicians, and it is difficult to achieve substantial energy saving activities due to management responsibility and material problems in case of equipment problems.

In order to solve these problems, a control device that controls and manages energy-using facilities to save energy must be operated automatically without system operator intervention.

However, in the case of a system that performs energy management in a building using a conventional BEMS, etc., the energy optimal control algorithm may function simultaneously depending on the target equipment, so the calculated control values may be different under certain conditions. In the case of such a conflict of control commands, there is a problem in that full automatic operation is impossible because a system operator has to intervene and perform the adjustment work directly.

On the other hand, the prior art related to the building automatic control system includes Korean Patent Registration No. 10-1710029.

The present invention has been devised to solve the problems of the prior art as described above. When a general control command of the building automatic control system itself and a BEMS control command of the building energy management system collide with a specific facility, a certain control command is used. The object of the present invention is to provide a building automatic control system and a control method capable of automatically operating without intervention of an administrator by automatically determining whether to execute or controlling the operation of a facility.

The problems to be solved by the present invention are not limited to the above-described problems, and other technical problems not mentioned will be clearly understood by a person having ordinary knowledge in the technical field to which the present invention pertains from contents to be described later.

The building automatic control system according to the present invention for achieving the above object is a building automatic control system with a built-in building energy management system (BEMS), and uses the energy saving control algorithm of the building automatic control system itself to issue general control commands. A general control command output unit for outputting; A BEMS control command output unit for outputting a BEMS control command using an energy saving control algorithm of the building energy management system (BEMS) embedded in the building automatic control system; A data processing unit providing information for outputting a control command to the general control command output unit and a BEMS control command output unit; An integrated management module that receives the general control command and the BEMS control command from the general control command output unit and the BEMS control command output unit, compares priorities, and selects and outputs a control command with a higher priority; And it characterized in that it comprises a; point management unit for controlling the operation of the equipment according to the control command output from the integrated management module.

In this case, the general control command output unit and the BEMS control command output unit output a plurality of control commands, respectively, and select a control command having the highest priority and transmit it to the integrated management module.

Also, the general control command output from the general control command output unit has a priority value of 1 to 16, and the BEMS control command output from the BEMS control command output unit has a priority value of 1 to 256. It is characterized by.

In addition, the integrated management module is characterized by performing a comparison with the priority of the general control command after dividing the priority value of the BEMS control command by 16.

In addition, the building automatic control system, when the general control command of the building automatic control system itself and the BEMS control command of the building energy management system collide, executes a control command based on a criterion preset by an administrator. It is characterized in that it is possible to automatically operate without intervention of the administrator by automatically determining the ground and controlling the operation of the facility.

On the other hand, the control method of the building automatic control system according to the present invention includes a step of providing information for outputting a control command from the data processing unit to a general control command output unit and a BEMS control command output unit; Step b, which outputs the general control command and the BEMS control command from the general control command output unit and the BEMS control command output unit based on the information received from the data processing unit, and transmits it to the integrated management module; After comparing the priority of the general control command and the BEMS control command received from the general control command output unit and the BEMS control command output unit in the integrated management module, select a control command having a higher priority and output it to the point management unit c step; And a step d of controlling the operation of the facility device according to a control command output from the point management unit through the integrated management module.

In this step c, the integrated management module is characterized in that it performs a comparison with the priority of the general control command after dividing the priority value of the BEMS control command by 16.

In addition, in the control method of the building automatic control system, when the general control command of the building automatic control system itself and the BEMS control command of the building energy management system collide, execute a control command based on a criterion preset by the administrator. It is characterized in that it is possible to automatically operate without intervention of the administrator by automatically determining the ground and controlling the operation of the facility.

The building automatic control system and the control method according to the present invention automatically determine which control command to execute when a general control command of the building automatic control system itself and a BEMS control command of the building energy management system collide for a specific facility. There is an effect that can be automatically operated without the intervention of the administrator by controlling the operation of the equipment.

The effects of the present invention are not limited to the effects mentioned above, and other effects not mentioned will be clearly understood by those skilled in the art from the description of the claims.

1 is a view showing a related configuration of a building automatic control system according to the present invention.
2 is a block diagram showing a detailed configuration of a building automatic control system according to the present invention.
3 is a flowchart showing a process for a control method of a building automatic control system according to the present invention.

With reference to the accompanying drawings, a preferred embodiment of the present invention will be described in more detail, but for the brevity of description, the technical parts that are already well-known will be omitted or compressed.

1 is a view showing a related configuration of a building automatic control system according to the present invention, FIG. 2 is a block diagram showing a detailed configuration of a building automatic control system according to the present invention, and FIG. 3 is a building automatic according to the present invention It is a flow chart showing the process of the control method of the control system.

As shown in FIG. 1, the building automatic control system 10 according to the present invention is built in a building and integrates various energy-related facility devices 20 (lighting facilities, air conditioning facilities, air conditioning facilities, power facilities, etc.) in the building. It is configured to control, manage, and send and receive various data, information, etc. with the control server (50).

The control server 50 can be connected to the control computer 51 so as to be communicatively connected, and the control computer 51 is implemented with a Man-Machine interface (MMI) to provide various information to a manager or a controller in a GUI (Graphic User Interface) environment. Provided as, the command signal input by the administrator is transmitted to the building automatic control system 10 according to the present invention according to a predetermined specification, and furthermore, information or data according to the request of the administrator of the building automatic control system 10 of the present invention It can be configured to be feedback from. In addition, the control server 50 may provide weather information (temperature, humidity, etc.) at the present time to the building automatic control system 10.

The building automatic control system 10 of the present invention is configured to be communicatively connected to a plurality of facility devices 20 to collect various information and to transmit various command signals for driving, operation, and monitoring of the facility devices 20. do.

In addition, the building automatic control system 10 of the present invention may directly measure or measure actual energy consumption, one or more measuring instruments 30 and one or more sensors capable of directly measuring temperature, humidity, brightness, etc. in a building ( 40).

The building automatic control system 10 of the present invention and other components communicatively connected to the building automatic control system 10 of the present invention can be connected to enable mutual communication through various communication networks including wired / wireless Internet, wired / wireless LAN, WiFi, and the like. You can.

On the other hand, Figure 2 is a block diagram showing a detailed configuration of a building automatic control system according to the present invention, Figure 3 is a flow chart showing a process for a control method of a building automatic control system according to the present invention.

Hereinafter, a detailed configuration and control method of the building automatic control system 10 according to the present invention will be described in detail with reference to FIGS. 2 and 3.

2, the building automatic control system 10 according to the present invention includes a basic information storage unit 11, a reference information storage unit 12, a data processing unit 13, a database 14, and general control. It may be configured to include a command output unit 15, a BEMS control command output unit 16, an integrated management module 17 and a point management unit 18.

Prior to the detailed description of the present invention, each component of the building automatic control system 10 according to the present invention shown in FIG. 2 should be understood as a logically divided component rather than a physically divided component.

That is, each configuration corresponds to a logical component for realizing the technical idea of the present invention, so that even if each component is integrated or separately configured, the function performed by the logical configuration of the present invention can be realized. It should be interpreted as being within the scope, and components that perform the same or similar functions should be interpreted as being within the scope of the present invention regardless of whether or not there is consistency in the name.

The basic information storage unit 11 includes ID information, management codes, standard usage information, usage information per unit time, installed year, life information, replacement cycles, etc. Basic information including energy type information for the type or type is stored.

The reference information storage unit 12 stores reference energy information that is a reference for proper energy consumption of the corresponding facility 20, and the reference energy information is minute, hour, day, quarter, season or It may mean information on the proper energy consumption that can be used in the corresponding facility device 20 on a yearly basis.

The data processing unit 13 receives basic information and reference information for the equipment 20 from the basic information storage 11 and the reference information storage 12, and each equipment 20 from the instrument 30 Received energy measurement information for, compares the current energy usage and reference energy information of each equipment 20 to determine whether proper energy is used or excessive energy is used in each equipment 20, The determined information is transmitted to the general control command output unit 15 and the BEMS control command output unit 16.

In addition, the data processing unit 13 receives data such as temperature, humidity, and illuminance (brightness) inside the building from the sensor 40, and receives weather information (temperature, humidity, etc.) at the present time from the control server 50. It is provided and calculates temperature difference, humidity difference, brightness difference, etc. inside and outside the building based on the current time, and transmits the calculated information to the general control command output unit 15 and the BEMS control command output unit 16.

At this time, the data processing unit 13 may transmit information collected from the respective components or finally determined information and calculated information to the manager terminal 52.

The manager terminal 52 is a terminal representing the manager, and may use the control PC 51 as an object of the manager terminal 52, but accurately distinguishes the manager and quickly transmits information to the manager, It is desirable to implement a mobile terminal such as a smart phone carried or carried by an administrator in order to quickly and accurately receive a command signal from.

The database 14 includes information provided from each component in the data processing unit 13 and energy consumption information at a specific point in time processed and produced by the data processing unit 13, temperature difference inside and outside the building, difference in humidity, difference in brightness, and manager It performs the function of storing and managing identification information and unique information of the manager terminal 52 in an integrated manner.

The general control command output unit 15 outputs a plurality of general control commands by using the energy saving control algorithm of the building automatic control system 10 itself based on the information received from the data processing unit 13, and then a plurality of general control The general control command having the highest priority among the commands is selected and transmitted to the integrated management module 17. At this time, the priority of the general control command has a value of 1 to 16, and the lower the number, the higher the priority. In addition, the priority criterion of each general control command that can be output is set in advance by the administrator.

The BEMS control command output unit 16 uses a number of BEMS control commands using the energy saving control algorithm of the building energy management system (BEMS) built into the building automation control system 10 based on the information received from the data processing unit 13. After outputting, the BEMS control command having the highest priority among the plurality of BEMS control commands is selected and transmitted to the integrated management module 17. At this time, the priority of the BEMS control command has a point value of 1 to 256, and the BEMS control command has a relatively large number, so the priority value is configured more widely than the general control command. The lower the number, the higher the priority. Means In addition, since the building energy management system (BEMS) function can be turned on / off by an administrator, the BEMS control command output unit when an administrator sets the building energy management system (BEMS) to off. (16) does not output the BEMS control command. In addition, the priority criterion of each BEMS control command that can be output is set in advance by the administrator.

The integrated management module 17 compares the priority of the general control command and the BEMS control command received from the general control command output unit 15 and the BEMS control command output unit 16, and then selects a control command with a higher priority. Output to the point management unit 18. At this time, the integrated management module 17 sets the priority value of the BEMS control command to compare the priority of the general control command having the priority value of 1 to 16 and the BEMS control command having the priority value of 1 to 256. After dividing by, it compares with the priority of the general control command. At this time, after dividing the priority value of the BEMS control command by 16, the decimal point is cut. In other words, when the priority value of the BEMS control command is divided by 16, if a decimal number such as 16.5 appears, the decimal point is cut and the comparison with the priority of the general control command is performed by 16. Detailed description thereof will be described later.

The point management unit 18 directly controls driving of the corresponding equipment 20 using the control command output through the integrated management module 17.

Hereinafter, a control method of the building automatic control system 10 according to the present invention will be described in detail with reference to FIG. 3.

First, in the state where the building energy management system (BEMS) function is set to ON by the administrator (S100), whether the proper energy is used in each equipment 20 in the data processing unit 13 or excessive energy is used. At the same time, it determines whether it is present and calculates the temperature difference, humidity difference, brightness difference, etc. inside and outside the building based on the current time, and outputs the determined information and the calculated information to the general control command output unit 15 and the BEMS control command output unit. (16).

Next, the BEMS control command output unit 16 uses a plurality of energy saving control algorithms of the building energy management system (BEMS) built into the building automation control system 10 based on the information received from the data processing unit 13. After outputting the BEMS control command (S110), the BEMS control command having the highest priority among the plurality of BEMS control commands is selected and transmitted to the integrated management module 17 (S120). At this time, the general control command output unit 15 also outputs a plurality of general control commands using the energy saving control algorithm of the building automatic control system 10 itself based on the information received from the data processing unit 13, and then multiple The general control command having the highest priority among the general control commands is selected and transmitted to the integrated management module 17.

Thereafter, the integrated management module 17 divides the priority value of the BEMS control command received from the BEMS control command output unit 16 by 16, and then the priority value of the general control command received from the general control command output unit 15. Compared with (S130), a control command having a higher priority is selected and output to the point management unit 18 (S150), and the point management unit 18 uses the control command output through the integrated management module 17. Directly controls the driving of the equipment 20 (S160).

Specifically, in a situation in which a heater, which is one of the facility devices 20 inside the building, is operating, in the BEMS control command output unit 16, the current energy consumption of the heater from the data processing unit 13 exceeds the reference energy consumption by a reference value The BEMS control command that immediately stops the operation of the heater having the priority value of 128 and the operation of the heater having the priority value of 144 are stopped for a certain time after receiving the information determined that the excess heater is using excessive energy. When a BEMS control command to restart is output, a BEMS control command to immediately stop the operation of the higher priority heater is selected and transmitted to the integrated management module 17.

In addition, in a situation in which a heater, which is one of the facility devices 20 inside the building, is operating, the current indoor / outdoor temperature difference received from the data processing unit 13 in the general control command output unit 16 is within a reference value, so When a general control command for maintaining the operation of the heater having the priority value and a general control command for reducing the operation intensity of the heater having the priority value of 8 are output, the general control for maintaining the operation of the heater having the higher priority. The command is selected and sent to the integrated management module 17.

Subsequently, the integrated management module 17 divides the priority value 128 of the received BEMS control command (the heater is immediately stopped) to 16 to compare the priority value of the BEMS control command and the general control command, and is received. It is compared with the priority value 7 of the control command (keep the heater running), and in this situation, the final priority value of the BEMS control command is 8 and the priority value of the general control command is 7, so the general control command priority. The higher the ranking, the last control command to maintain the operation of the heater, which is a general control command, is finally output to the point management unit 18, so that the point management unit 18 controls the heater to continue to operate.

At this time, if the priority value of the BEMS control command is divided by 16 and the priority value of the general control command is the same, it is a principle to output the control command entered later, but an exception may be made by the administrator's settings as needed. . In addition, when the general control command of the building automatic control system itself and the BEMS control command of the building energy management system collide as described above, the controller automatically determines which control command to execute based on the criteria set in advance by the administrator. It can be operated automatically without administrator intervention.

On the other hand, if the building energy management system (BEMS) function is set to OFF (S100) by the administrator, or if a separate BEMS control command is not output from the BEMS control command output unit 16 (S110) , Selects the general control command having the highest priority among the plurality of general control commands output from the general control command output unit 15 (S200) and transmits it to the integrated management module 17, and receives the integrated management module 17 The general control command is output to the point management unit 18 (S150), and the point management unit 18 directly controls the driving of the corresponding equipment 20 using the control command output through the integrated management module 17. (S160).

 In the above, it has been described based on a single facility device 20, but of course, all of the plurality of facility devices 20 can be individually controlled.

As described in detail above, the building automatic control system and its control method according to the present invention are subject to certain control commands when the general control command of the building automatic control system itself and the BEMS control command of the building energy management system collide for a specific facility. There is an effect that can be automatically operated without the intervention of the administrator by automatically determining whether or not to control the operation of the equipment.

As described above, the detailed description of the present invention has been made by the embodiments with reference to the accompanying drawings. However, since the above-described embodiments are merely described as preferred examples of the present invention, the present invention is limited to the above-described embodiments only. It should not be understood as being, and the scope of the present invention should be understood as the claims and the equivalent concept described later.

10: Building automatic control system
11: Basic information storage
12: Reference information storage
13: data processing unit
14: database
15: general control command output
16: BEMS control command output
17: Integrated management module
18: point management department
20: Equipment
30: measuring instrument
40: sensor
50: control server
51: control computer
52: administrator terminal

Claims (8)

In the building automatic control system with a built-in building energy management system (BEMS),
A general control command output unit for outputting a general control command using the energy saving control algorithm of the building automatic control system itself;
A BEMS control command output unit for outputting a BEMS control command using an energy saving control algorithm of the building energy management system (BEMS) embedded in the building automatic control system;
A data processing unit providing information for outputting a control command to the general control command output unit and a BEMS control command output unit;
An integrated management module that receives the general control command and the BEMS control command from the general control command output unit and the BEMS control command output unit, compares priorities, and selects and outputs a control command with a higher priority; And
Building automatic control system comprising a; point management unit for controlling the operation of the equipment according to the control command output from the integrated management module.
According to claim 1,
The general control command output unit and the BEMS control command output unit output a plurality of control commands, respectively, and select a control command having the highest priority and transmit it to the integrated management module.
According to claim 2,
The general control command output from the general control command output unit has a priority value of 1 to 16,
The BEMS control command output from the BEMS control command output unit has a priority value of 1 to 256, the building automatic control system.
According to claim 3,
The integrated management module divides the priority value of the BEMS control command by 16, and then compares it with the priority of the general control command.
The method according to any one of claims 1 to 4,
The building automatic control system,
When the general control command of the building automatic control system itself collides with the BEMS control command of the building energy management system, it automatically determines which control command to execute based on a preset criterion by an administrator to drive the facility. Building control system characterized in that it can be operated automatically without the intervention of the administrator by controlling the.
A step of providing information for outputting a control command from the data processing unit to a general control command output unit and a BEMS control command output unit;
Step b, which outputs the general control command and the BEMS control command from the general control command output unit and the BEMS control command output unit based on the information received from the data processing unit, and transmits it to the integrated management module;
After comparing the priority of the general control command and the BEMS control command received from the general control command output unit and the BEMS control command output unit in the integrated management module, select a control command having a higher priority and output it to the point management unit c step; And
Controlling the building automatic control system comprising a; step d to control the operation of the equipment according to the control command output through the integrated management module from the point management unit.
The method of claim 6,
In step c, the integrated management module divides the priority value of the BEMS control command by 16, and then compares it with the priority of the general control command.
The method of claim 6 or 7,
The control method of the building automatic control system,
When the general control command of the building automatic control system and the BEMS control command of the building energy management system collide, it automatically determines which control command to execute based on a criterion preset by the administrator to control the operation of the equipment. By controlling the building automatic control system, characterized in that it can be operated automatically without the intervention of the administrator.

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