KR200365831Y1 - A thermostat make use of power line communication - Google Patents

Abstract

Heating control device using power line communication is to control the heating is made through the power line communication between the components for heating control. The present invention is located inside or outside the boiler or the circulating pump case, the heating controller to control the boiler or circulation pump by transmitting and receiving data to the power line, the control unit to control each valve by sending and receiving data to the power line, and each individual Sub-room cones for heating control, and main room cones for the overall heating control is configured to connect two-way communication to the power line. Therefore, the present invention does not require a complicated wire connection from the boiler or the circulation pump to the valve of the room, and checks this in the heating controller when the boiler or the circulation pump fails, and checks it in each control controller when the valve or valve actuator fails. By sending the fault information to the screen or subroom cone to display on the screen, the user can easily check it.

Description

Heating thermostat using power line communication {A thermostat make use of power line communication}

The present invention relates to a boiler control using a power line, more specifically, to control the heating in the room cone without the need for complicated wired connection by connecting the two-way communication between the power control line and the heating controller and the room cone through the power line, boiler or circulation pump or valve The present invention relates to a heating control device using power line communication to identify a failure of the lamp.

Boiler installation is essential for indoor heating and hot water use in various buildings. However, when the boiler is installed, most of them are connected by wired cables, which may cause shortcomings due to construction difficulties, complicated piping, and wiring, and high cost of equipment. Therefore, in recent years, a number of prior art techniques for controlling a boiler by connecting through an existing power line (power line) has been proposed. Examples are shown in FIGS. 1A-1B.

1A-1B is a conventional boiler control using a power line, FIG. 1A is a control system of a hot water distributor using a power line, and FIG. 1B is a boiler control device using a power line modem.

The control system shown in FIG. 1A is provided on one side of the hot water distributor 3 for supplying hot water from the boiler to each room, and controls a power line with a controller (each control controller) 5 for controlling the automatic valve 4 of each discharge pipe. Each room is equipped with a master temperature controller (main room cone) (1) having a temperature control function and an electrical connection with the master temperature controller (1) and a temperature display unit, a function button or a status display lamp. It consists of a thermostat (subroom cone) (2). Each room thermostat 2 controls the controller 5 via a power line and at the same time has a temperature control function in the other room. The controller 5 is connected to the boiler or circulation pump (M) via a connecting line.

As such, in the control system of FIG. 1A, a master temperature controller 1, which is a main room cone, and a controller 5, which is a room control controller, are connected by power line communication. However, since the boiler, the circulation pump, and the controller 5 are connected by serial communication through the connection line, the difficulties of wired connection still exist depending on the installation position of each valve and each control controller, so that the advantages of power line communication cannot be utilized properly. do.

On the other hand, the boiler control device shown in Figure 1b is a blocking filter (BF) (11) for preventing the signal interference of the signal flows from the power line modem (PLM) to the neighboring home through the power line (Power Line) and each component module The power line modem 12 for combining and transmitting the data through the power line or receiving the data transmitted through the power line to each of the corresponding configuration modules, and the boiler controller BC for controlling the operation of the boiler 13 And a main room cone (MC) 14 that controls the temperature of the boiler and controls the traffic of each component module, and one or more subroom cones 15 installed in each room to adjust the temperature of each room. And, and remote control using a wireless communication system such as a telephone / cell phone / wireless pager and consists of a telephone control module (TCM) 16 to receive the control results and the status of the boiler.

As such, the boiler control device of Figure 1b receives the command of the main room cone 14 in the boiler controller 13 controls the operation of the boiler and opens and closes the valve of the room. That is, when a user inputs a data value higher than the current temperature for the heating operation, the main room cone 14 converts it into power line communication data and sends this value to the boiler controller 13. Then, the boiler controller 13 converts this value into serial data to control the operation of the boiler and to open and close the corresponding valve. The boiler controller 13 opens the valve of the room and starts the pump after a certain time delay. At this time, the boiler controller 13 and the valve of the room is connected by wire to perform serial communication.

However, in general, the boiler controller can only control the "on / off (OFF)" of the boiler, but does not control the lateral valve, so the prior art of Figure 1b is not practical production.

Therefore, an object of the present invention is to connect each control module and the heating controller of the boiler to the bidirectional communication via the room cone and the power line to control the valves of each room without the need for complicated wired connection, all of the configuration module related to heating control by power line communication mutual data The present invention provides a heating control device using power line communication to control the heating by transmitting and receiving and to confirm a failure of a boiler or a circulation pump or a valve.

1a-1b is a configuration diagram showing examples of boiler control using a conventional power line,

2 is a block diagram showing a heating control device using a power line communication according to the present invention,

3 is a flow chart for explaining the operation at the heating stop of the heating control device of FIG.

4 is a flowchart illustrating an operation during heating operation of the heating control device of FIG.

5 is a flow chart for explaining the freeze protection operation of the heating control device of FIG.

Figure 6 is a flow chart for explaining the operation during failure of the heating control device of FIG.

<Description of the symbols for the main parts of the drawings>

21 (1),... , 21 (n): main room cone 22 (1),... , 22 (n): Subroom cone

23: power line 24: heating controller

25: boiler / circulation pump 26: each room control controller

27: serial communication line

Heating control device using the power line communication of the present invention for achieving the above object, is installed in each room in the heating control device of the boiler, by converting the heating start / stop command for individual heating control of each room into power line communication data A main room cone for receiving and analyzing power line communication data of the subroom cone for transmission, and converting the boiler and each valve control command into power line communication data according to an analysis result, and connected to the boiler; And receiving and converting the power line communication data of the main room cone into serial data, and a heating controller for starting / stopping the boiler according to the analysis result by analyzing the converted serial data, and receiving and receiving the power line communication data of the main room cone. Convert the data and analyze the converted serial data according to the analysis result Each room control controller for opening and closing the room valve, and a power line for bidirectional communication connection of the above components.

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

2 shows a block diagram of a heating control apparatus using power line communication according to the present invention. The heating control device shown in Figure 2 is installed in the room or living room, etc. Main room cone (21 (1), ..., 21 (n)) for controlling the room temperature as a whole, the sub-room cone (22) for each individual heating control installed in each room (1),..., 22 (n)), each control controller 26 for opening and closing each valve, and a heating controller 24 for wired connection with the boiler or circulation pump 25 to start or stop heating. Equipped. Each component is connected to a power line 23 of AC 220V, and performs bidirectional communication. Here, the heating controller 24 is located inside or outside the boiler or circulation pump 25 case, the main room cone (21 (1), ..., 21 (n)) or the sub-room cone (22 (1), ..., 22) (n)) receives the power line communication data is converted into serial communication data to control the boiler or the circulation pump (25). Each room control controller 26 is located near the hot water distributor (not shown), and is connected to each room hot water supply valve driver (not shown) by wire, so that the main room cones 21 (1), ..., 21 (n) or sub It receives the power line communication data from the room cones 22 (1), ..., 22 (n), converts the power line communication data into serial communication data, and transmits an opening / closing command to the valve driver controlling the valve of the room. An operation of the heating control device using the power line communication of FIG. 2 having such a configuration will be described in detail with reference to FIGS. 3 to 6.

First, the operation at the time of stopping heating will be described with reference to FIG. 3.

The user inputs and sets a desired room temperature value through the operation panel on the subroom cone 22 (step 301). The subroom cone 22 compares the present temperature with the set temperature (step 302), and generates heating stop command data when the present temperature is higher than the set temperature (step 303). The subroom cone 22 converts the generated heating stop command into power line communication (PLC) data (step 304) and transmits it to the main room cone 21 via the power line 23 (step 305).

The main room cone 21 receives power line communication data from the subroom cone 22 via the power line 23 (step 306), and analyzes the received data (step 307). When the received data is analyzed by the heating stop command, the main room cone 21 checks whether another room is currently heating up (step 308). Here, the reason for checking the heating state of the other side is that if the other room is in the heating operation state, only the valve of the room is closed and the heating is stopped. If the other room is the heating stop, the boiler operation is stopped first to stop the heating water circulation and then the valve. By closing the valve to prevent overheating of the boiler circulation pump when the valve is closed first. If the check result of step 308 indicates that the other is heating, the main room cone 21 converts the command to stop heating only the room corresponding to the subroom cone 22 that requested the heating stop into power line communication (PLC) data (step 309). In operation 310, the control unit 26 transmits the power to the control controller 26 via the power line 23.

Each room control controller 26 receives power line communication data from the main room cone 21 via the power line 23 (step 311), and analyzes the received data (step 312). Each room control controller 26 transmits a close command to the valve driver corresponding to the room for which the heating stop is requested according to the analysis result (step 313), and closes the valve (step 314). Each control controller 26 transmits the valve closed state to the main room cone 21 through the reverse path when the valve is closed.

If the check in step 308 indicates that the other one is not heating, the main room cone 21 first converts the boiler stop command into power line communication data (step 315) and transmits it to the heating controller 24 through the power line 23 ( Step 316).

The heating controller 24 receives the power line communication data from the main room cone 21 via the power line 23 (step 317), and converts the received data into serial communication data (step 318). The heating controller 24 analyzes the data converted into the serial communication form (step 319), and when analyzed by the boiler stop command, transmits a stop command to the boiler 25 through the serial communication line 27 (step 320). Stop (step 321). When the boiler 25 is stopped, the heating controller 24 transmits the boiler stop state to the main room cone 21 through the reverse path.

When the main room cone 21 reports the boiler stop state from the heating controller 24, the main room cone 21 returns to step 309 to repeat the step to lock the room valve.

Next, the operation | movement at the time of heating operation is demonstrated through FIG.

When the user inputs and sets a desired room temperature value on the subroom cone 22 (step 401), the subroom cone 22 compares the present temperature with the set temperature (step 402). If the present temperature is lower than the set temperature as a result of the comparison in step 402, the subroom cone 22 generates heating operation command data (step 403) and then converts it into power line communication data (step 404). The subroom cone 22 transmits power line communication data of a heating operation command to the main room cone 21 through the power line 23.

The main room cone 21 receives power line communication (PLC) data through the power line 23 and analyzes the received data (step 405). When the received data is analyzed by the heating operation command, the main room cone 21 checks whether the other is currently in heating operation (step 406). Here, the reason for confirming the other heating operation at present is to send a command to start the boiler 25 when the current state of the boiler 25 is stopped, and to send an operation command when the current state of the boiler 25 is operating. Because there is no. If the check in step 406 indicates that the other one is in heating operation, the main room cone 21 converts the command for heating only the room corresponding to the subroom cone 22 that has requested heating operation into power line communication data (step 407), and the power line ( 23) is transmitted to each room control controller 26.

Each room control controller 26 receives power line communication (PLC) data via the power line 23 (step 408) and analyzes the received data (step 409). Each room control controller 26 transmits an opening command to the valve driver corresponding to the room requesting the heating operation according to the analysis result (step 410), and opens the valve (step 411). Each control controller 26 transmits the valve open state to the main room cone 21 through the reverse path when the valve is opened.

If the check in step 406 indicates that the other is not heating, the main room cone 21 must first open the room valve and then operate the boiler 25, and then convert the command into power line communication data (step 412). The power line 23 is used to transmit to the respective room control controllers 26. Each room control controller 26 receives the power line communication (PLC) data through the power line 23 (step 413) and then analyzes the received data (step 414). Each room control controller 26 transmits an opening command to the room valve driver according to the analysis result (step 415), and opens the valve (step 416). Then, when the main room cone 21 informs the room valve opening state from each control controller 26 through the power line 23, the heating controller (power line communication data corresponding to the boiler operation command) through the power line 23 24).

The heating controller 24 receives the power line communication (PLC) data through the power line 23 and converts it into serial data (step 417). The heating controller 24 analyzes the received data converted into the serial communication form (step 418), and transmits an operation command to the boiler 25 according to the analysis result (step 419), and starts the boiler 25 (step 420). The heating controller 24 transmits the boiler operating state to the main room cone 21 through the reverse path when the boiler 25 is operated.

Next, a freeze protection operation will be described with reference to FIG. 5.

Typically, a temperature sensor (not shown) is provided at the heating water inlet side of the boiler 25 to detect the water temperature to prevent the boiler 25 from freezing. That is, the heating controller 24 determines whether the heating water temperature detected by the temperature sensor (not shown) is equal to or lower than a predetermined temperature (here, 4 ° C.) (step 501). If the heating water temperature is 4 ° C. or less as a result of the determination in step 501, the heating controller 24 generates the freeze protection mode operation data (step 502), and then converts it into power line communication data (step 503), through the power line 23. The main room cone 21 is transmitted.

The main room cone 21 receives the power line communication (PLC) data through the power line 23 and analyzes the received data (step 504), performs the freeze protection mode and displays it on the screen (step 505). In the freeze protection mode, the main room cone 21 converts a control command for freeze protection into power line communication data (step 506) and then transmits the control command to each room control controller 26 through the power line 23.

Each room control controller 26 receives power line communication (PLC) data via the power line 23 (step 507). Each room control controller 26 analyzes the received data (step 508), and transmits an open command to the whole room valve driver (step 509) to prevent freezing according to the analysis result (step 509), and opens the valve (step 510). Each room control controller 26 transmits the valve open state to the main room cone 21 through the reverse path when the whole room valve is opened.

When the main room cone 21 informs the whole room valve open state from each room control controller 26, the main room cone 21 transmits the corresponding power line communication data to the heating controller 24 through the power line 23 again.

The heating controller 24 receives the power line communication (PLC) data through the power line 23 and converts it into serial data (step 511). The heating controller 24 analyzes the received data converted into the serial communication form (step 512), and transmits an operation command to the boiler 25 to prevent freezing according to the analysis result (step 513), and sends the boiler 25 to it. Start up (step 514). The heating controller 24 transmits the boiler operating state to the main room cone 21 through the reverse path when the boiler 25 is operated.

Next, the operation at the time of failure will be described with reference to FIG. 6.

Each control controller 26 transmits a valve operation command to each valve driver (step 601), and determines whether the valve is activated from the response signal thereto (step 602). If the valve is not operated as a result of the determination in step 602, each control controller 26 recognizes as a failure and generates valve failure data (step 603). Each control controller 26 converts the generated valve failure data into power line communication data so as to be transmitted through the power line 23 (step 604), and transmits it to the main room cone 21. The main room cones 21 interconnected via the power lines 23 receive and analyze the power line communication (PLC) data transmitted from each control controller 26 (step 605). If the analysis result of the step 605 is a valve failure, the main room cone 21 displays a failure icon on the screen to enable the user to recognize the failure.

As described above, the heating control device using the power line communication of the present invention, the heating-related components are connected to the two-way communication through the power line to transmit and receive data to each other to control the heating, each room heating start and stop, freeze prevention, breakdown, etc. Users can easily check the status of the transmission and reception, and do not need complicated wired construction, and has the effect that can be flexibly applied to the installation situation of each installation.

Claims (7)

In the heating control device of the boiler, A subroom cone installed in each room and converting heating start / stop commands for individual heating control into power line communication data for transmission; A main room cone for receiving and analyzing the power line communication data of the subroom cone and converting the boiler and each valve control command into power line communication data according to an analysis result; A heating controller connected to the boiler for converting the power line communication data of the main room cone into serial data and analyzing the converted serial data to start / stop the boiler according to the analysis result; Receiving the power line communication data of the main room cone converted into serial data, each room control controller for opening and closing the corresponding room valve according to the analysis result by analyzing the converted serial data; And Heating control apparatus using power line communication comprising a power line for connecting the two-way communication. The heating controller according to claim 1, wherein the heating controller is located at one of the inside and the outside of the boiler or the circulating pump case and is connected to the main room cone by a power line, and is connected by a wire to the boiler or the circulation pump. Device. The method of claim 2, wherein the heating controller transmits the failure information to the main room cone or sub-room cone through the power line so that the user can check it on the screen of the main room cone or sub-room cone when a boiler or circulation pump failure occurs. Heating control device using power line communication. The power line communication of claim 2, wherein the heating controller converts the freeze protection mode operation data into power line communication data when the heating water temperature of the boiler is lower than a preset temperature and transmits the power line communication data to the main room cone through the power line. Heating control device used. The heating control apparatus according to claim 1, wherein each of the room control controllers is connected to the main room cone by a power line and is connected by wire to each of the room valves. The power line according to claim 5, wherein the respective room control controller transmits fault information to the main room cone or the subroom cone through the power line so that a user can check the screen of the main room cone or the subroom cone when the valve breaks down. Heating control device using communication. The method of claim 4, wherein the main room cone If the received power line communication data is a heating stop command, it checks the current heating status of the other side and controls to close only the valve of the room requesting the heating stop when the other room is in heating operation, and stops the boiler operation first when the other room is in the heating stop state. To stop the heating water circulation and close the valve, If the received power line communication data is a heating start command, check the current heating state of the other side and control to open only the valve of the room requesting heating if the other room is in heating operation state, and if the other room is in the heating stop state, Open the valve first and then control the boiler to run, If the received power line communication data operation command in the freeze protection mode, the heating control device using the power line communication, characterized in that for controlling the operation of the boiler after opening the entire room valve first.