KR20100019623A - Control method according to change of heating load in individual heating control system and individual heating control system using the method - Google Patents

Abstract

PURPOSE: A method for controlling a boiler according to the change of heating load in an individual heating control system is provided to prevent noise from the inside of a heating pipe by controlling the output plate number of a circulation pump according to the heating load. CONSTITUTION: Those are detected that difference between a temperature of circulated water for heating after passing through a heating pipe(2) of each room, and a temperature of supply water which passes through a heat-exchanger(50). A controller(90) presently calculates the cycle oil amount of hot-water from the detected temperature difference and current boiler control calorie of the controller. The controller reduces the control calorie of the boiler, when the calculated heating-water flow rate is reduced. The controller increases the control calorie of the boiler, when the calculated heating-water flow rate increases.

Description

Control method of boiler according to heating load variation in individual heating control system and individual heating control system using same {Control Method according to change of heating load in individual heating control system and individual heating control system using the method}

The present invention relates to a control method of a boiler according to a heating load variation in an individual heating control system and an individual heating control system using the same. More specifically, the present invention relates to a control method for increasing or decreasing the control heat quantity of the boiler and the output stage of the circulation pump according to the change of the heating load in the individual heating control system, and the individual heating control system using the same.

In general, a boiler is a device that heats water through heat transfer in a heat exchanger, and circulates the heated water to a heating pipe in a room to heat it or to supply hot water to a user. The boiler is controlled by an indoor temperature controller installed indoors.

In recent years, according to the needs of each room user who wants to control the heating temperature individually, an individual heating control system has been developed to control the heating temperature differently in each room through an indoor temperature controller installed in a plurality of rooms individually.

In the general individual heating control system shown in Figure 1, each of the heating pipes 2, which are piped from the boiler 1 to a specific indoor floor divided into a room, and the flow rate of the heating water supplied to the heating pipe (2) Each heating valve (3) for controlling the heating, the heating valve controller (4) for controlling the presence or absence of heating water by controlling the opening and closing of the heating valve, and the room installed in each room so that the user can control the room temperature And a thermostat 5.

FIG. 2 is a graph showing a change in temperature of heating supply water and heating return and control heat of a boiler according to a change in heating load (heating water circulation flow rate) in a conventional individual heating control system. Here, the heating supply water refers to the heating water after passing through the heat exchanger of the boiler 1 and before being supplied to each heating pipe 2, and the heating return water passes the heat of the hot water while passing through each heating pipe 2. Refers to the heating water coming back into the boiler afterwards.

In the individual heating control system, when a command is inputted to stop the heating of some of the room temperature controllers 5 of each room during the heating operation for the entire room, at time t1, the heating valve controller 4 performs the heating valve ( To lock 3). Accordingly, the total heating water circulation flow rate circulating inside the individual heating control system is drastically reduced from Q1 to Q2.

However, the boiler of the conventional individual heating control system is not equipped with a system capable of changing the control heat amount of the boiler in accordance with the change in the heating water circulation flow rate, it was only possible to control the operation / shutdown of the boiler. Therefore, even when the heating water circulation flow rate is reduced, since the boiler continues to supply the same heat amount, the temperature of the heating water supply is rapidly increased from T1 to T2.

In a typical boiler, the boiler may be overheated when the temperature of the heating feed water is about 85 ° C. or higher, so that the controller shuts down the boiler as at time t2. After a period of time after the boiler has stopped operating, if the temperature of the heating feed water drops below a certain temperature, the boiler starts operation again at time t3. However, even in this case, while the control heat amount of the boiler is the same, while the heating water circulation flow rate is kept reduced, the temperature of the heating supply water rises again to T2. When the temperature of the heating feed water is about 85 ° C. or higher again, the boiler may be overheated, so that the controller stops the operation of the boiler at time t4. Likewise, if the temperature of the heating feed water falls below a certain temperature as time passes, the boiler starts operation again at time t5, and stops the operation of the boiler at time t6 when the temperature reaches about 85 ° C or more.

As such, in the conventional individual heating control system, when the heating is stopped in some rooms, the heating water circulation flow rate decreases while the control heat quantity of the boiler does not change, so the boiler operation / stop is repeated for a short time. It was not possible to perform a smooth heating, there was a problem that the durability of the boiler is also reduced.

In addition, when the heating valve 3 of some rooms is locked during the heating operation for the entire room, the speed of the heating water passing through the heating valve 3 of the remaining rooms becomes faster. As the speed increases, the pressure in the portion is lowered, and there is a problem in that noise is generated while bubbles are generated in the heating water due to the cavitation phenomenon caused by the pressure drop.

Therefore, the present invention has been invented in view of the above circumstances, and by changing the control heat quantity of the boiler in accordance with the heating load change in the individual heating control system, the heating load fluctuations in the individual heating control system to enable the heating of the boiler smoothly It is an object to provide a control method of a boiler and an individual heating control system using the same.

In addition, by adjusting the output stage of the circulating pump of the boiler according to the change of the heating load, the control method of the boiler according to the heating load change and the individual heating control using the same in the individual heating control system that can prevent the generation of noise inside the heating pipe The purpose is to provide a system.

The control method of the boiler according to the heating load change in the individual heating control system for circulating the heating water passing through the heat exchanger through the heating pipe divided into each room according to the control of the boiler controller of the present invention to perform individual heating for each room, Measuring a temperature difference between the heating return water returned after passing through each heating pipe and the heating supply water passing through the heat exchanger of the boiler; A controller calculating a heating water circulation flow rate circulating in the boiler from the measured temperature difference and the current boiler control heat of the controller; The controller is characterized in that it comprises the step of controlling to increase the control heat amount of the boiler when the calculated heating water circulation flow rate decreases, and increases the control heat quantity of the boiler when the heating water circulation flow rate increases.

In addition, the boiler includes a circulating pump having a multi-stage output, and the controller reduces the output stage of the circulation pump when the calculated heating water circulation flow rate decreases, and output stage of the circulation pump when the heating water circulation flow rate increases. It characterized in that it further comprises the step of controlling to increase.

In addition, the controller is characterized in that the control to increase or decrease the control heat of the boiler and the output stage of the circulation pump stepwise.

The individual heating control system of the present invention is a return temperature sensor for measuring the temperature of the heating water returned after passing through the heating pipe, a heat exchanger for transmitting the combustion heat of the burner to the heating water, and a circulation for supplying the returned heating water to the heat exchanger A boiler comprising a pump, a feed water temperature sensor for measuring the temperature of the heating water passing through the heat exchanger, and a controller for controlling a series of combustion processes and operation of the boiler; Respective heating pipes piped to a specific area divided into rooms; Respective heating valves for controlling a flow rate of the heating water supplied to the heating pipe; And a heating valve controller for controlling the presence or absence of heating water and temperature by controlling the opening and closing of the heating valve, wherein the controller of the boiler controls the temperature difference between the heating supply water and the heating return water by the supply water temperature sensor and the return water temperature sensor. Measure and calculate the heating water circulation flow rate circulating in the boiler from the measured temperature difference and the current control heat quantity of the controller. When the calculated heating water circulation flow rate decreases, the control heat quantity of the boiler is reduced, and the heating water circulation flow rate The increase is characterized in that the control to increase the control heat of the boiler.

In addition, the circulation pump has a multi-stage output, and the controller controls to reduce the output stage of the circulation pump if the calculated heating water circulation flow rate decreases, and to increase the output stage of the circulation pump if the heating water circulation flow rate increases. Characterized in that.

In addition, the controller is an individual heating control system, characterized in that for controlling step by step to increase and decrease the control heat of the boiler and the output stage of the circulation pump.

According to the present invention, by changing the control heat amount of the boiler in accordance with the change in the heating load in the individual heating control system, there is an advantage to enable a smooth heating by keeping the temperature of the heating supply water relatively constant.

In addition, according to the change in the heating load in the individual heating control system, by adjusting the output stage of the circulation pump of the boiler it is possible to prevent the generation of noise inside the heating pipe, there is an advantage that the power consumption is reduced.

Hereinafter, the configuration and operation of the preferred embodiment of the present invention will be described in detail with reference to the accompanying drawings. Here, in adding reference numerals to the elements of each drawing, it should be noted that the same elements are denoted by the same reference numerals as much as possible even if they are shown in different drawings.

3 is a view showing a schematic configuration of an individual heating control system 101 according to the present invention.

The individual heating control system 101, the boiler 100, each of the heating pipes (2) piped to a specific indoor floor divided into a room, and the flow rate of the heating water supplied to the heating pipe (2) Each heating valve 3 to be adjusted, a heating valve controller 4 for controlling the presence or absence of heating water by controlling the opening and closing of the heating valve, and an indoor temperature installed in each room so that the user can control the indoor temperature. Regulator 5.

The boiler 100 has a return temperature sensor 10 for measuring the temperature of the heating water passing through each heating pipe (2), the expansion tank 20 for storing a portion of the heating water, air and A burner 40 which burns a gas mixture to generate combustion heat, a heat exchanger 50 which transfers combustion heat of the burner 40 to heating water, and a circulation pump which supplies heating water to the heat exchanger 50. 30, a feed water temperature sensor 60 for measuring the temperature of the heating water passing through the heat exchanger, a hot water heat exchanger 70 for heating the water supply by the heating water heated in the heat exchanger 50, and a boiler Three-way valve (80) to selectively open and close the heating line and hot water line of the, and to control the series of combustion process and operation of the boiler Controller 90.

In addition, the circulation pump 30 in the present invention, for example, is composed of a multi-stage pump that can change the output in three stages. Here, the third stage represents the highest output and the first stage represents the lowest output.

4 is a graph showing a change in temperature of heating supply water and heating return water, a change in control calorific value of a boiler and an output stage of a circulation pump 30 according to a change in a heating water circulation flow rate in the individual heating control system of the present invention. to be.

In the individual heating control system of the present invention, the controller 90 of the boiler 100 calculates the change in the heating water circulation flow rate at regular time intervals.

Heating water circulation flow rate can be calculated | required from the following formula | equation.

Q = m * C * Δt equation (1)

m = Q / (C * Δt) equation (2)

Where Q is the control heat of the boiler per unit time, m is the heating water circulation flow rate, C is the specific heat of water, and Δt is the temperature difference between the heating supply water and the heating return water.

The control calorific value of the boiler per unit time is a value that the controller knows as the heat capacity that the controller is currently trying to obtain by controlling the burner's thermal power. Is obtained from the measured value of. Therefore, the heating water circulation flow rate is calculated from the above formula (2).

When a command to stop heating in some of the room temperature controllers 5 of each room is input at time t1, the heating valve controller 4 locks the heating valve 3 of the corresponding room. Accordingly, when the total heating water circulation flow rate is reduced from Q1 to Q2 (for example, 6L <Q2 ≤ 10L), the heating heat circulation temperature is increased because the heating flow rate of the boiler is constant while the heating water circulation flow rate is reduced. To start.

The controller 90 checks this at t2 after a predetermined time elapses after the heating water circulation flow rate decreases, and immediately reduces the control heat amount of the boiler in two stages according to the heating water circulation flow rate. Here, the second stage refers to a predetermined reduced control heat amount set by the controller of the boiler.

At the same time as reducing the control heat of the boiler, the controller 90 lowers the output stage of the circulation pump from three stages to two stages. As the output stage of the circulation pump is lowered, the heating water circulation flow rate through the boiler pipe per unit time is also reduced accordingly. Although the heating water circulation flow rate is reduced, the heating power temperature of the boiler is lowered since the control heat quantity of the boiler is significantly reduced compared to the heating water circulation flow rate is reduced.

If in some rooms additional heating is stopped at time t3, and the total heating water circulation flow is reduced from Q3 to Q4 (eg Q4 ≤ 6L), the boiler's control heat is still constant while the heating water circulation flow is As it decreases, the heating feed water temperature starts to rise again.

The controller 90 further reduces the heating water circulation flow rate, checks it at t4 after a predetermined time elapses, and immediately reduces the control heat amount of the boiler to the first stage according to the heating water circulation flow rate, and simultaneously reduces the output of the circulation pump. Reduce from 2 to 1 As the output stage of the circulation pump is lowered, the heating water circulation flow rate is also reduced accordingly. Although the heating water circulation flow rate is reduced, the heating power temperature of the boiler is lowered since the control heat quantity of the boiler is significantly reduced compared to the heating water circulation flow rate is reduced.

As heating starts again in all rooms where heating is stopped at time t5, if the total heating water circulation flow rate is increased from Q5 to Q6 (eg Q6> 10L), the boiler's control calories are still the same as before Since the water circulation flow rate increases considerably, the heating feed water temperature starts to fall sharply.

The controller checks this at t6 after the heating water circulation flow rate is increased again, and immediately increases the control heat of the boiler according to the heating water circulation flow rate, and simultaneously increases the output of the circulation pump from one stage to three stages. Increase. As the output stage of the circulation pump increases, the heating water circulation flow rate also increases accordingly.

Although the heating water circulation flow rate is increased, the heating power of the boiler starts to rise again because the control heat of the boiler is increased more significantly than the heating water circulation flow rate is increased.

As described above, in the individual heating control system 101 of the present invention, the controller 90 calculates the total heating water circulation flow rate at a predetermined time interval, and thus adjusts the control heat amount of the boiler according to the increase and decrease of the heating water circulation flow rate. . Therefore, the phenomenon that the heating supply water temperature rises rapidly does not occur, and is maintained within a certain range. Therefore, as in the conventional individual heating control system, the phenomenon in which the operation of the boiler is repeated according to the fluctuation of the heating water circulation flow rate does not occur. Therefore, smooth operation of the boiler becomes possible, and the cause of deterioration of the durability of the boiler does not occur.

In addition, the controller 90 changes the amount of control heat of the boiler and simultaneously adjusts the output stage of the circulation pump 30 according to the increase and decrease of the heating water circulation flow rate. That is, when the heating water circulation flow rate is reduced, the output stage of the circulation pump 30 is reduced, and when the heating water circulation flow rate is increased, the output stage of the circulation pump 30 is increased. Therefore, the pressure difference in the heating pipe 2 is reduced by that, and the cavitation phenomenon generated by the pressure difference inside the pipe does not occur, so that noise inside the pipe is prevented. In addition, since the output stage of the circulation pump is controlled low, the power consumption can be reduced.

5 is a flowchart illustrating an exemplary method of controlling the control heat amount of the boiler 100 and the output stage of the circulation pump 30 in accordance with the variation of the heating water circulation flow rate in the individual heating control system of the present invention.

First, the controller 90 determines whether the boiler is burning (S10).

When the boiler is burning, the controller 90 controls the thermal power of the burner to a control heat amount corresponding to the heat capacity to be obtained (S20). In addition, the controller controls the output of the circulation pump in three stages (S30).

Next, the controller determines whether the change in the control calorific value is within ± 1% for 3 seconds or more (S40). If the change in the control calorific value is not within ± 1% for 3 seconds or more, the process returns to step S20.

When the change in the control calorific value is within ± 1% for 3 seconds or more, the controller determines whether the temperature change of the heating supply water and the heating return water is within ± 0.5% for 6 seconds or more (S50). If the temperature change of the heating supply water and the heating return water is not within ± 0.5% for 6 seconds or more, the process returns to step S20.

When the temperature change of the heating supply water and the heating return water is within 6 seconds to within 0.5%, the heating water circulation flow rate is calculated from the current control heat amount of the boiler and the temperature difference between the heating supply water and the heating return water (S60).

Next, it is determined whether the heating water circulation flow rate calculated in step S60 is 10L or less (S70). When the heating water circulation flow rate exceeds 10L, the output of the circulation pump is controlled in three stages, and the flow returns to step S20 (S71).

If the heating water circulation flow rate is less than 10L, it is determined whether or not again within 6L (S80). When the heating water circulation flow rate exceeds 6L and is within 10L, the circulation pump and the control heat amount are controlled in two stages, and the flow returns to step S40 (S81).

If the heating water circulation flow rate is within 6L, the circulation pump and the control heat amount are controlled in one stage, and the flow returns to step S40 (S90).

It will be apparent to those skilled in the art that various modifications and variations can be made in the present invention without departing from the spirit and scope of the invention will be.

1 is a view showing a schematic configuration of a conventional heating control system of the prior art.

2 is a graph showing a change in temperature of heating water supply and heating return and control heat of a boiler according to a change in heating load (heating water circulation flow rate) in an individual heating control system according to the related art.

3 is a view showing a schematic configuration of an individual heating control system according to the present invention.

4 is a graph showing the temperature change of the heating supply water and the heating return water, the change in the control calorific value of the boiler and the output stage change of the circulation pump in the individual heating control system according to the present invention.

Figure 5 is a flow chart illustrating an exemplary method for controlling the control heat of the boiler and the output stage of the circulation pump in accordance with the variation of the heating water circulation flow rate in the individual heating control system of the present invention.

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

2: heating piping 3: heating valve

4: heating valve controller 5: room temperature controller

10: return temperature sensor 20: expansion tank

30: circulation pump 40: burner

50: heat exchanger 60: feed water temperature sensor

70: hot water heat exchanger 80: three-way valve

90: controller 101: individual heating control system

Claims (6)

In the control method of the boiler according to the heating load change in the individual heating control system for circulating the heating water passing through the heat exchanger through the heating piping divided into each room under the control of the boiler controller to perform individual heating for each room, Measuring a temperature difference between the heating return water returned after passing through each heating pipe and the heating supply water passing through the heat exchanger of the boiler; A controller calculating a heating water circulation flow rate circulating in the boiler from the measured temperature difference and the current boiler control heat of the controller; The controller may include controlling to reduce the control heat of the boiler when the calculated heating water circulation flow rate decreases, and to increase the control heat of the boiler when the heating water circulation flow rate increases. Control method of boiler according to heating load change in The boiler of claim 1, wherein the boiler includes a circulation pump having a multi-stage output, and the controller reduces the output stage of the circulation pump when the calculated heating water circulation flow rate decreases, and circulates when the heating water circulation flow rate increases. The control method of the boiler according to the heating load change in the individual heating control system, characterized in that it further comprises the step of controlling to increase the output stage of the pump. The method according to claim 1 or 2, wherein the controller controls to increase or decrease the control heat of the boiler and the output stage of the circulating pump in a stepwise manner. . A return temperature sensor that measures the temperature of the returned heating water after passing through the heating pipe, a heat exchanger that transfers the combustion heat of the burner to the heating water, a circulation pump that supplies the returned heating water to the heat exchanger, and heating that passes through the heat exchanger A boiler comprising a feed water temperature sensor for measuring the temperature of the water, and a controller for controlling a series of combustion processes and operation of the boiler; Respective heating pipes piped to a specific area divided into rooms; Respective heating valves for controlling a flow rate of the heating water supplied to the heating pipe; And including a heating valve controller for controlling the opening and closing of the heating valve to control the supply and temperature of the heating water, The controller of the boiler measures the temperature difference between the heating supply water and the heating return water by the feed water temperature sensor and the return water temperature sensor, and calculates a heating water circulation flow rate circulating in the boiler from the measured temperature difference and the current control heat of the controller. Calculating, when the calculated heating water circulation flow rate decreases, the control heat quantity of the boiler is reduced, and when the heating water circulation flow rate increases, the individual heating control system characterized in that the control to increase the control heat quantity of the boiler. The output pump of claim 4, wherein the circulation pump has a multi-stage output, and the controller reduces the output stage of the circulation pump if the calculated heating water circulation flow rate decreases, and increases the output stage of the circulation pump if the heating water circulation flow rate increases. Individual heating control system, characterized in that for controlling to increase. The individual heating control system according to claim 4 or 5, wherein the controller controls to increase or decrease the control heat of the boiler and the output stage of the circulation pump stepwise.

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