KR102230281B1 - BEMS for total controlling power equipment - Google Patents

Abstract

According to an embodiment of the present invention, a building energy management system performing power facility integrated control communications, comprises: a first power facility which is connected to an integrated management unit by a power line communications line, and whose operation is controlled by a first control signal received from the integrated management unit through the power line communications line; a second power facility which is connected to a power facility expansion communications unit by a LAN communications line instead of the power line communications line, and whose operation is controlled by a second control signal received from the power facility expansion communications unit through the LAN communications line; a power facility expansion communications unit which is connected to the second power facility by the LAN communications line, and transmits a second control signal received from the integrated management unit to the second power facility through the LAN communications line; a detection unit which generates detection information including temperature information and transmits the generated detection information to the integrated management unit through the power line communications line; and an integrated management unit which has a reception module for receiving the detection information, a first data processing module for generating a first control signal to control the first power facility according to the detection information, a first transmission module for transmitting the first control signal to the first power facility through the power line communications line, a second data processing module for generating a second control signal to control the second power facility according to the detection information, and a second transmission module for transmitting the second control signal to the power facility expansion communications unit.

Description

Building energy management system performing integrated control communication of power facilities {BEMS for total controlling power equipment}

The present invention relates to a building energy management system that provides a building energy management system (BEMS) that enables integrated controllable communication of power facilities.

As issues related to environment-friendliness and energy saving have become more concentrated in recent years, various infrastructure structures are being introduced that enable more efficient use of energy. As a part of these efforts, systems to increase the efficiency of energy use for the entire building, such as the Building Energy Management System (BEMS), are being constructed in large buildings such as schools, collective buildings, and factories in recent years.

BEMS is being used to effectively manage energy resources used in buildings by monitoring energy usage status information such as air conditioning facilities, air conditioning facilities, lighting facilities, and power facilities, and using the monitored results.

Typically, device groups by type that use power or energy are installed in buildings by individual manufacturers or system companies along with related infrastructure structures and facilities, so many of the equipment and infrastructure structures for control, monitoring or control are installed in duplicate. It is common to be.

This redundant installation itself not only increases the cost, but also requires additional installations to be integrated in order to operate and control the facilities/devices individually installed for each individual entity at the whole building level, so the efficiency is low and further integrated control is also possible. However, since it is performed at the level of simply connecting the control devices that control individual device groups, the efficiency of the integrated control itself is degraded, and there is a limit that it is difficult to perform real-time processing that immediately responds to a specific situation.

In addition, since the use of the internal space constantly changes over time according to structural changes according to the building age, usage change, and increase or decrease of the number of users, etc., if the system infrastructure is not constructed in a structure that can easily adapt to such spatial changes, piping wiring Changes, electric wire line replacement, and related facility expansion/reduction/addition must be accompanied at any time, so it can be said that there is a fundamental limitation in effectively managing the energy of the entire building.

In particular, even if centrally controlled devices (e.g., air conditioners such as lighting, heaters, air conditioners, etc.) are integrated and controlled by the system, devices such as air conditioners that are individually additionally installed by users in the building are blind spots of integrated control. Because it is placed in, it becomes difficult to efficiently perform unified energy management.

Korean Patent Registration No. 10-1944022 (2019.01.24)

An object of the present invention is to provide a building energy management system (BEMS) having a communication function that enables efficient management by integrating power facilities such as air conditioners that are individually additionally installed by users in a building.

An embodiment of the present invention is a first power facility connected to the integrated management unit by a power line communication line, the drive is controlled by a first control signal received from the integrated management unit through the power line communication line; A second power facility that is connected to the power facility expansion communication unit by a LAN communication line rather than a power line communication line, and is driven by a second control signal received from the power facility expansion communication unit through a LAN communication line; A power facility expansion communication unit connected to the second power facility by a LAN communication line and transmitting a second control signal received from the integrated management unit to the second power facility through a LAN communication line; A sensing unit that generates sensing information including temperature information and transmits it to an integrated management unit through a power line communication line; A receiving module receiving the sensing information, a first data processing module generating a first control signal to control a first power facility according to the sensing information, and the first power facility receiving the first control signal through a power line communication line. And a second data processing module that generates a second control signal to control a second power facility according to the sensing information, and transmits the second control signal to the power facility expansion communication unit. It may include; an integrated management unit having a second transmission module.

The power facility expansion communication unit includes: a power line communication module for performing power line communication with the integrated management unit; A UDP communication module for performing UDP communication through the second power facility and a LAN communication line; And a communication processing module for relaying a second control signal received from the integrated management unit through the power line communication module to the second power facility through a UDP communication module.

The power facility expansion communication unit includes a reception status notification module for providing a second control signal reception status, which is a reception status of the second control signal in the second power facility, to the communication processing module, wherein the communication processing module comprises: , It is possible to transmit a second control signal reception state received through the reception state notification module to the integrated management unit.

The reception status notification module may perform Bluetooth communication with the second power facility, receive a second control signal reception status from the second power facility through Bluetooth communication, and provide the received state to the communication processing module.

According to an embodiment of the present invention, by providing a power facility expansion communication unit, power facilities that are individually additionally installed by a user in a building can be integrated and controlled by a central building energy management system (BEMS).

In addition, according to an embodiment of the present invention, it is possible to immediately identify a state in which UDP communication is disabled between the power facility expansion communication unit and the additionally installed power facility, thereby preventing the state in which the additionally installed power facility cannot be controlled due to the inability of UDP communication. can do.

1 is a block diagram of a building energy management system for performing integrated power facility control communication according to an embodiment of the present invention.
Figure 2 is a block diagram of the configuration of a power facility expansion communication unit according to an embodiment of the present invention.
3 is a block diagram of a configuration of a power facility expansion communication unit equipped with a reception status notification module according to an embodiment of the present invention.
Figure 4 is a block diagram of the configuration of a power facility expansion communication unit equipped with a reset signal notification module according to an embodiment of the present invention.
5 is an exemplary diagram of generating a reset signal and reporting it to a second power facility according to an embodiment of the present invention.

Hereinafter, embodiments according to the present invention will be described with reference to the accompanying drawings. In adding reference numerals to elements of each drawing, it should be noted that the same elements are assigned the same numerals as possible, even if they are indicated on different drawings. In addition, in describing an embodiment of the present invention, if it is determined that a detailed description of a related known configuration or function interferes with an understanding of the embodiment of the present invention, the detailed description thereof will be omitted. In addition, embodiments of the present invention will be described below, but the technical idea of the present invention is not limited or limited thereto, and may be modified and variously implemented by those skilled in the art.

1 is a configuration diagram of a building energy management system for performing integrated control communication of power facilities according to an embodiment of the present invention, FIG. 2 is a block diagram of a configuration of a power facility expansion communication unit according to an embodiment of the present invention, and FIG. A block diagram showing a configuration of a power facility expansion communication unit equipped with a reception status notification module according to an embodiment of the present invention, and FIG. 4 is a configuration block diagram of a power facility expansion communication unit equipped with a reset signal notification module according to an embodiment of the present invention. Fig. 5 is an exemplary diagram in which a reset signal is generated and reported to a second power facility according to an embodiment of the present invention.

In the following description, the term "power equipment" refers to various power equipment installed inside and outside a building, such as cooling and heating equipment, air conditioning equipment, lighting equipment, power equipment, and the like, and operated using power energy.

Building energy management system for performing integrated power facility control communication of the present invention, as shown in Figure 1, the first power facility 410, the detection unit 100, the integrated management unit 200, the second power facility ( 420), may include a power facility expansion communication unit 300.

The first power facility 410 is a facility such as a cooling and heating facility connected to the integrated management unit 200 by a power line communication line. The first power facility 410 is a facility capable of power line communication by being equipped with a power line communication processing processor capable of processing power line communication. Accordingly, the driving of the first power facility 410 is controlled by the first control signal received from the integrated management unit 200 through power line communication performing power line communication. For reference, as is known, power line communication (PLC) refers to a technology for communicating through a power line rather than a dedicated communication line, and when a power line is used, communication is possible without a separate wiring.

The sensing unit 100 is a unit that generates sensing information including temperature information and transmits sensing information to the integrated management unit 200 through a power line communication line. Here, the sensing information is a configuration for one or more sensors that detects information on whether a person exists in a specific space, as well as various environmental information such as humidity, dust, fine dust, Co2, etc., in addition to temperature. ) In addition, it is connected to the power line to be communicatively connected and is configured to transmit the sensed various sensing information to the integrated management unit 200, which is a component of the present invention. Of course, these configurations could also be connected via a wireless network.

The integrated management unit 200, when various detection information is received from the detection unit 100, is a control signal corresponding to the received detection information using predetermined schedule control information (hereinafter, for controlling the first power facility 410). A signal is referred to as a'first control signal'), and the generated first control signal is transmitted to the corresponding first power facility 410 to control the driving of the first power facility 410.

To this end, the integrated management unit 200 controls the first power facility 410 using a receiving module 210 for receiving detection information from the detection unit 100, and schedule control information predetermined according to the detection information. A first data processing module 221 for generating a first control signal, and a first transmission module 231 for transmitting the first control signal to the first power equipment 410 through a power line communication line.

Furthermore, such a first control signal can be generated and transmitted in an automated method using predetermined schedule control information according to the transmitted detection signal. However, depending on the embodiment, the input signal according to the judgment of the central manager, etc. It can also be treated by, for example.

On the other hand, even if centrally controlled devices (e.g., air conditioners such as lighting, heaters, air conditioners, etc.) are integrated and controlled by the system using power line communication, users in the building may individually install additionally installed air conditioners, etc. Since power facilities do not have power line communication functions, they are placed in the blind spot of integrated control, making it difficult to efficiently manage unified energy.

In consideration of this problem, the building energy management system for performing integrated power facility control communication of the present invention includes a separate power facility expansion communication unit 300. It will be described in detail below.

The second power facility 420 refers to a power facility that does not have a power line communication processing processor capable of processing power line communication (PLC), and includes, for example, an air conditioner used in a general office where power line communication processing is not possible. Can be. The second power facility is equipped with a LAN port and is a device capable of processing LAN communication such as UDP communication. Therefore, the second power facility 420 is connected to the power facility expansion communication unit 300 by a LAN communication line rather than a power line communication line, and the second control signal received from the power facility expansion communication unit 300 through the LAN communication line. Driving is controlled by this. For reference, if a communication hardware module is provided, the second power facility 420 may be implemented to enable communication processing necessary in the present invention through software update.

The integrated management unit 200 communicates with a second data processing module 222 that generates a second control signal to control the second power facility 420 that is additionally installed according to the sensing information, and a second control signal. It includes a second transmission module 232 for transmitting to the power facility expansion communication unit 300 through.

The power facility expansion communication unit 300 is connected to the second power facility 420 by a LAN communication line rather than a power line communication line, and transmits a second control signal received from the integrated management unit 200 to the second power through the LAN communication line. It is transmitted to the facility 420. Therefore, by connecting the second power facilities 420 newly added by each individual to the power facility expansion communication unit 300, the integrated management unit 200 controls the integrated management unit 200 even for the second power facility 420 in which power line communication is impossible. Becomes possible.

The power facility expansion communication unit may be connected by adding each second power facility 420, and thus, a number of second power facilities 420 may be expanded and connected.

The power facility expansion communication unit 300 includes a power line communication module 310, a UDP communication module 330, and a communication processing module 320 as shown in FIG. 2.

The power line communication module 310 is a module that performs power line communication (PLC communication) with the second transmission module of the integrated management unit 200.

The UDP communication module 330 is a module that performs UDP communication with the second power facility 420 through a LAN communication line. Since the LAN communication line is implemented as a LAN communication line through which UDP communication is performed between the power facility expansion communication unit 300 and the second power facility 420, it is implemented as a UDP communication module that performs UDP communication.

The reason for implementing the UDP communication between the power facility expansion communication unit 300 and the second power facility 420 is not TCP communication as follows. TCP guarantees reliable message reception, but the efficiency can be reduced for the exchange of various control messages, and it has the disadvantage that it supports only one-to-one transmission for retransmission of data, so the generated data can be transmitted continuously. It uses UDP communication with good transmission efficiency.

The communication processing module 320 relays and transmits the second control signal received from the integrated management unit 200 through the power line communication module 310 to the second power facility 420 through the UDP communication module 330. That is, the second control signal received from the integrated management unit 200 is converted into protocol packet data matching UDP communication and relayed to the second power facility 420.

On the other hand, in general, Internet-based communication services through LAN communication lines use TCP (Transmission Control Protocol), which provides reliable communication to the upper level based on IP (Internet Protocol), or User Datagram Protocol (UDP), which provides unreliable communication. It may be provided as a basis. Here, in the TCP communication, it is necessary to check the reception status of the transmitted message through the exchange of various control messages, and to ensure the reception of the message stably at the receiving side by adjusting the transmission rate. Therefore, although TCP guarantees reliable message reception, efficiency may be degraded for exchanging various control messages, and it has disadvantages that only one-to-one transmission is supported for data retransmission.

On the other hand, UDP (User Datagram Protocol) communication is a transmission service having unreliability, and since it can continuously transmit the generated data, the transmission efficiency of data is good, and there is no need to maintain the reception state of the data, so multicasting (multicasting). And a communication service capable of broadcasting.

Therefore, the power facility expansion communication unit 300 and the second power facility 420 of the present invention communicate using UDP communication having good control signal transmission/reception efficiency, but UDP communication is correlated with whether or not the transmitting side receives the receiving side. Since data is transmitted without data, there is a disadvantage that the reliability of the data cannot be secured. In other words, when the transmitting end and the receiving end perform UDP communication, the transmitting end unilaterally transmits data regardless of the state of the receiving end. Therefore, the data reliability is improved because the transmitting end does not check the data reception status and perform retransmission. Cannot provide.

Therefore, in order to receive reliable data such as TCP (Transmission Control Protocol) with the efficiency of data transmission provided by UDP while using a UDP-based communication service, the power facility expansion communication unit 300 of the present invention is shown in FIG. As shown in FIG. 1, a separate reception status notification module 340 for notifying the reception status of the second control signal is further provided.

The reception status notification module 340 provides a second control signal reception status, which is a reception status of the second control signal in the second power facility 420, to the communication processing module 320. Here, the reception status notification module 340 communicates with the second power facility 420 via Bluetooth, and receives a second control signal reception status from the second power facility 420 through Bluetooth communication to the communication processing module 320. Can provide. Therefore, when a Bluetooth communication module is provided in the second power facility 420, the reception state of the second control signal can be provided to the communication processing module 320 through the reception state notification module 340 through Bluetooth communication. .

Therefore, the communication processing module 320 transmits the reception status of the second control signal received through the reception status notification module 340 to the integrated management unit 200, and the integrated management unit 200 is If 420 is normally receiving the second control signal through UDP communication, it continues to transmit the second control signal. On the other hand, the second power facility 420 normally receives the second control signal through UDP communication. If not, it is possible to take measures such as notifying the manager of a reception error of the second power facility 420.

In addition, if the second power facility 420 is not normally receiving the second control signal through UDP communication, as another embodiment, the integrated management unit 200 does not notify the administrator and the second power facility 420 itself By resetting, the UDP communication can be initialized so that a normal second control signal is received.

To this end, the power facility expansion communication unit 300 includes a reset signal notification module 350 for transmitting a second power facility reset signal through Bluetooth communication with the second power facility 420 as shown in FIG. 4. do. Therefore, when the second power facility reset signal is received from the integrated management unit 200 through the power line communication module, the communication processing module 320 transmits the second power facility reset signal through the reset signal notification module 350. It is transmitted to the power equipment 420.

On the other hand, if the second power facility 420 is not normally receiving the second control signal through UDP communication, as described above, the power facility expansion communication unit 300 integrates and manages the second power facility reset signal. It is possible to reset the second power facility 420 by receiving it from the unit 200, but for a quick response, the power facility expansion communication unit 300 is itself the second power facility 420 without the involvement of the integrated management unit 200. ) Can be implemented to reset.

To this end, the communication processing module 320 of the power facility expansion communication unit 300, as shown in FIG. 5, when the reception state of the second control signal received through the reception state notification module 340 is in a state in which reception is impossible, The second power facility reset signal is generated by itself without notifying the integrated management unit 200 and transmitted to the second power facility 420 through the reset signal notification module 350. Therefore, it is possible to initialize the UDP communication by immediately resetting the second power facility 420 without going through the integrated management unit 200, so that a communication inability state can be immediately resolved.

As described above, an optimal embodiment has been disclosed in the drawings and specifications. Although specific terms have been used herein, these are only used for the purpose of describing the present invention, and are not used to limit the meaning or the scope of the present invention described in the claims. Therefore, those of ordinary skill in the art will understand that various modifications and equivalent other embodiments are possible therefrom. Therefore, the true technical protection scope of the present invention should be determined by the technical spirit of the appended claims.

100: detection unit 200: integrated management unit
300: power facility expansion communication unit
410: first power facility 420: second power facility

Claims (4)

A power facility equipped with a power line communication processing processor capable of processing power line communication (PLC), which is connected to the integrated management unit by a power line communication line, and is driven by a first control signal received from the integrated management unit through the power line communication line. A controlled first power facility;
A power facility that does not have a power line communication processing processor capable of processing power line communication (PLC), and is connected to the power facility expansion communication unit by a LAN communication line rather than a power line communication line, and the power facility expansion communication unit through a LAN communication line. A second power facility in which driving is controlled by a second control signal received from the second power supply;
A power facility expansion communication unit connected to the second power facility by a LAN communication line and transmitting a second control signal received from the integrated management unit to the second power facility through a LAN communication line;
A sensing unit that generates sensing information including temperature information and transmits it to an integrated management unit through a power line communication line;
A receiving module receiving the sensing information, a first data processing module generating a first control signal to control a first power facility according to the sensing information, and the first power facility receiving the first control signal through a power line communication line. And a second data processing module that generates a second control signal to control a second power facility according to the detection information, and transmits the second control signal to the power facility expansion communication unit. Including; an integrated management unit having a second transmission module,
The power facility expansion communication unit includes: a power line communication module for performing power line communication with the integrated management unit; A UDP communication module for performing UDP communication through the second power facility and a LAN communication line; A communication processing module for relaying a second control signal received from the integrated management unit through the power line communication module to the second power facility through a UDP communication module; And a reception status notification module for providing a second control signal reception status, which is a reception status of the second control signal in the second power facility, to the communication processing module,
The communication processing module transmits a second control signal reception state received through the reception state notification module to the integrated management unit,
The reception status notification module performs Bluetooth communication with the second power facility, receives a second control signal reception status from the second power facility through Bluetooth communication, and performs power facility integrated control communication provided to the communication processing module,
The power facility expansion communication unit includes; a reset signal notification module for transmitting a second power facility reset signal through Bluetooth communication with the second power facility and through Bluetooth communication,
The communication processing module, when a second power facility reset signal is received from the integrated management unit through the power line communication module, transmits the second power facility reset signal to the second power facility through the reset signal notification module, and , When the receiving state of the second power facility received through the receiving state notification module is in an unreceivable state, a second power facility reset signal is generated by itself without notifying the integrated management unit, and the second power is transmitted through the reset signal notification module. Building energy management system capable of integrated control of power facilities, characterized by transmission to facilities. delete delete delete

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