KR20050075908A - Individation control process of valve - Google Patents

Abstract

The present invention is characterized in that by adjusting each valve on the main controller, by setting each valve in the main remote control for each room, even if a plurality of coils are installed in one room, it is possible to control the plurality of valves.

In addition, the present invention is to control the temperature of each pipe separately according to the individual adjustment to the valve on the main controller to eliminate the deviation of the temperature and at the same time to minimize the consumption of energy.

In addition, the present invention is to maximize the user satisfaction and reliability by improving the overall efficiency and economic efficiency.

Description

Individual control method of each control valve {INDIVIDATION CONTROL PROCESS OF VALVE}

The present invention is to individually control the valves on the main controller so as not to vary the temperature due to the partial heating, by setting the position of each valve on the main remote control to individually control the control valve of each room to select the valve for each room It is about a method,

More specifically, by controlling each valve on the main controller, and by setting each valve to each room in the main remote control, it is possible to control a plurality of valves even if a plurality of coils are installed in one room, the main controller The temperature of each pipe can be controlled separately according to the individual adjustment of the valves in the bed so that there is no deviation of the temperature and the energy consumption is minimized accordingly, thereby improving the overall efficiency and economic efficiency. It relates to an individual control method of each control valve to maximize the satisfaction and reliability.

In the related art, as shown in FIGS. 1 and 2, in order to recognize the respective pipes in the case where two or more heating coils 2-1 which are heating coils are installed in one room 1-1. The remote controller 3-1 is installed as many as the number of the valve 4-1, or it is made to control by grouping in the same line to recognize two or more pipe coils 2-1 in one remote controller 3-1. As a result, there is a problem of economical loss and troublesome installation of two or more remote controllers 3-1 in one room 1-1, and lengths of pipes installed in one room 1-1 are different. The bottom temperature of the pipe is installed long section is lower than the bottom temperature of the pipe installed section is a problem that the deviation of the other temperature occurs in one shot.

Therefore, due to the problems described above, the remote control of each room recognizes only one valve, so that the temperature controller for two or more pipe coils is connected to each other to control by setting only one valve to load the two pipe coils. Even if the temperature difference is caused by the car, it is not only able to cope with it quickly, but also the inconvenience of connecting the coil of the distributor into the room to the same terminal on the main controller. There is a problem that the satisfaction and reliability of the deterioration.

The present invention has been made to solve the problems of the prior art as described above has the following object.

The present invention is to control each of the valves on the main controller, and by setting each valve to each room in the main remote control, it is possible to control the plurality of valves even if a plurality of coils are installed in one.

Another object of the present invention is to control the temperature of each pipe separately according to the individual adjustment to the valve on the main controller to eliminate the deviation of the temperature and at the same time to minimize the consumption of energy.

Still another object of the present invention is to maximize user satisfaction and reliability by improving overall efficiency and economy.

Hereinafter, with reference to the accompanying drawings, a preferred embodiment for achieving the above object of the present invention will be described in detail.

In describing the present invention, when it is determined that the detailed description of the related known function or configuration may unnecessarily obscure the subject matter of the present invention, the detailed description thereof will be omitted.

Terms to be described later are set in consideration of functions in the present invention, which may vary depending on the intention or custom of users, experimenters, and producers, and the definitions thereof should be made based on the contents throughout the present specification.

That is, the present invention is to specify a unique number for recognizing each of the plurality of heating valves, and the unique number of each valve on the remote control that can be set and control the temperature of all rooms on the remote control for each valve Recognizing step, the recognition on the remote control to enable the recognition of two or more valves in one remote control, the valve is also made to be recognized by a plurality of remote control, and the temperature of the room is set by the user for heating operation control Identifying the number of valves passing through each room when reaching a temperature, and if the temperature deviation of the valve passing through the room is within 5 ℃ through the above, close the valve passing through the room to partially heat In order to prevent the temperature difference caused by.

On the other hand, in the step-by-step method of practicing the present invention can be variously modified and can take various forms.

It is to be understood, however, that the present invention is not limited to the specific forms referred to in the above description, but rather includes all modifications, equivalents and substitutions within the spirit and scope of the invention as defined by the appended claims. It should be understood to do.

First, as shown in FIG. 3, this is an exemplary configuration diagram of a system for applying the present invention to be executed as described above, in the case of the first valve 11 installed in the first chamber 10. The first remote control 11-1 is set by the first remote control 11-1, and the second valve 12 is also installed in the first chamber 10 and is recognized by the first remote control 11-1. In the case of the valve 21, since it is provided in the 2nd chamber 20, it is recognized by the 2nd remote control 22. As shown in FIG.

When the user performs the heating operation by setting the room temperature of the first room 10 to 20 ° C. for the temperature control through the above system, when the temperature of the first room 10 reaches 20 ° C., the Comparing the temperature of the first valve 11 and the temperature of the second valve 12, the heating water temperature of the first valve 11 is 50 ℃ and the heating water temperature of the second valve 12 is 60 ℃. In this case, the second valve 12 of the distributor 5 is closed, and the first valve 11 is kept open for a predetermined time, and the deviation of the two valves 11 and 12 is within 5 ° C. The 1st valve 11 of the distributor 5 can also be closed, and partial heating can be eliminated.

As shown, 1 is a boiler, 2 is a main controller, 3 is a temperature sensing unit for sensing temperature, 4 is a position recognition unit for recognizing the position of the valve, and 13, 14, and 23 are pipes installed in each room. It shows a coil.

In order to describe the present invention in more detail, the present invention will be described with reference to the flowcharts shown in FIGS. 4 to 6.

First, Figure 4 is a flow chart for recognizing the valve for each room on the main controller, the number of valves (K) installed in the distributor, the total number of distributors (M = 0) and the number of valves installed valves in the distributor (N (0) is initialized by checking (S10), and then a process (S11) is performed in which the '1' is increased (N = N + 1) with respect to the number of valves in which the valve is installed.

At this time, when the increased valve number N is greater than the number K of valves installed in the distributor (S12) compared with the number K of valves installed in the distributor (S12) (N> K ) If the setting is to be finished (S13), otherwise, the number of valves (N) is selected (S14) and '1' is increased (M = M + 1) to the total number (M) of the distributor (S15). Will be executed.

Based on this, the total number M of distributors is set (S16), and when the total number M of distributors is set, the total number M of distributors is initialized (M = 0) and fed back (S17). .

In addition, Figure 5 is a flow chart to detect the number of valves in operation on the initial total distributor, at the same time the position of the valves in operation, and to check the connection status with the remote control installed in the room to detect and display errors in the event of an error. to be.

That is, after the total number (M) of distributors (S20) is set (S20), the distributor checks the number of valves (N = 0) and the number of valves (K = 0) installed in the distributor (S21) to initialize (S21) and then initializes the above. In the distributor, a process (S22) in which '1' is increased (N = N + 1) with respect to the number of valves installed with the valve is performed.

And, in which the driving (S23) the valve (V _N) corresponding with respect to the valve number (N) of the valve installed in the distributor and the next thereto recognize whether confirmation (S24) for, if you are not recognized by the process of the above (S22 Is fed back.

If it is recognized in the above, the process (S25) '1' is increased (K = K + 1) with respect to the number of valves (K) installed in the dispenser is performed, the number of valves (K) installed in the dispenser It is recognized (S26) that the corresponding valve (V _N ) is the same with respect to the valve (V _K ) and the number of valves (N) where the valve is installed in the distributor.

On the other hand, if it is confirmed in the distributor that the valve number (N) in which the valve is installed is greater than the total number (M) of distributors (N> M) (S27), the process moves to the next process, otherwise the process ( S22) is fed back.

At this time, if it is confirmed that the large (N> M) in the above, confirm the number of valves (K = 0, B = K) installed in the distributor (S28) and then '1 for the number (K) of valves installed in the distributor The process (S29) is increased (K = K + 1), and the corresponding valve (V _K ) is driven (S30) with respect to the number K of valves installed in the distributor.

The state of position recognition (S31) and thermistor (TH) recognition (S32) for temperature sensing are respectively confirmed with respect to the driving of the corresponding valve (V _K ), and the communication signal is transmitted to the remote controller (S33). do.

At this time, if the thermistor (TH) recognition for the position recognition and temperature sensing is not performed in the above state, it is confirmed that an abnormality is generated and detects and displays an error (S35). Also, the communication signal of the remote controller is received. If it is not (S34), it is confirmed that an abnormality has occurred and an error is detected and displayed (S35).

If there is no problem with the corresponding valve in the above, the number of valves installed in the distributor is compared (S36) and the overall system if the number of valves (K) is larger than the set number (B) of valves (K> B). Initialization of is completed (S37).

For the sake of understanding the above description, for example, when six valves are installed in an eight ball distributor, M = 8, N = 6 and K = 6.

FIG. 6 is a flowchart illustrating a heating control process for setting a room temperature. First, when the room temperature is set (S40) and then the number of valves passing through the set room is one or less (S41), the set temperature is reached. Check whether (S42) to close the valve (S43), otherwise feed back, check whether the control temperature has reached in the state that the valve is closed (S44) if it reaches to open the valve (S45) Will be executed.

In addition, when the number of valves passing through the room set above is greater than one, it is checked whether the set temperature has been reached (S46), and if not, feedback to the whole process.

At this time, when the set temperature is reached in the above, the temperature deviation of the valve passing through the set room is checked (S47). If the temperature is 5 ° C. or less, all valves passing through the set room are closed (S48). and (S51) only closes the valve (V _max) of the temperature.

If all the valves passing through the set room have reached the control temperature in the closed state (S49), if it has reached, operate all the above valves to open (S50), and if the control temperature is not reached, the whole process It will give feedback to execute repeatedly.

In addition, in the state in which only the valve V _max of the highest temperature is closed (S51), the temperature of the remaining open valves is compared (S52). In the case of 5 ° C. or more, it is repeatedly executed to close only the valve V _(max−1) of the second highest temperature lower than the highest temperature (S51).

In accordance with the present invention, by controlling the valves individually on the main controller to control the temperature variation by partial heating, and by setting the position of each valve on the main remote control, You can choose a valve that fits.

As described above, the present invention is to control the respective valves on the main controller, and by setting each valve to each room in the main remote control, even if a plurality of coils are installed in a single effect that can be adjusted for a plurality of valves In addition, it is possible to control the temperature of each pipe separately according to the individual adjustment of the valve on the main controller, so that the variation of the temperature is eliminated, and the effect of minimizing the energy consumption is improved. The user's satisfaction and reliability can be maximized at the same time.

1 is an exemplary configuration diagram of a conventional application system of a boiler;

2 is another exemplary configuration diagram of a conventional boiler application system;

3 is an exemplary configuration diagram of a system for applying the present invention;

4 is a flowchart for recognizing a valve for each room on the main controller according to the present invention;

Figure 5 is a flow chart for identifying the number of valves in accordance with the present invention and check the connection of the remote control and recognition of the valve,

6 is a flowchart illustrating a heating control process for setting a room temperature according to the present invention.

<Description of the code | symbol about the principal part of drawing>

1: boiler 2: main controller

3: temperature sensing unit 4: position recognition unit

10: first room 11: first valve

12: second valve 20: second room

21: third valve 22: second remote control

Claims (1)

Designating a unique number for recognizing each of the plurality of heating valves; Recognizing the unique number of each valve on the remote control for each valve on the main remote control capable of temperature setting and control of all rooms; Enabling recognition of two or more valves in one remote controller by recognition on the remote controller, and also enabling valves to be recognized in a plurality of remote controllers; Determining the number of valves passing through each room when the temperature of the room reaches a temperature set by the user for heating operation control; If the temperature deviation of the valve passing through the room through the grasp of the above within 5 ℃ to close the valve passing through the room to prevent the temperature difference due to the partial heating; Individual control method of each control valve, characterized in that executed as.