KR101906220B1 - Exhaust gas temperature control method for a boiler - Google Patents

Abstract

The present invention relates to a method for controlling the temperature of an exhaust gas of a boiler, and more particularly, it relates to a method for controlling the exhaust gas temperature of a boiler, ); Confirming the controlled calorie (Q) of the current combustor; The present control quantity Q is compared with the formula defined by the slope (a) and the offset value (b) of the exhaust temperature relationship with respect to the heat exchange rate relative to the heat exchange rate of the heat exchanger stored in the storage device, Calculating a boundary temperature (T1) at the water return temperature; Confirming the current return temperature (Tin) of the heating water; Determining whether the current return temperature Tin is higher than the boundary temperature T1; Determining whether the supply control temperature Tset is higher than a predetermined limit exhaust gas temperature T2 if the current return temperature Tin is higher than the boundary temperature T1; And exhausting the combustor if the supply control temperature Tset is lower than or equal to the predetermined limit exhaust gas temperature T2.
Therefore, the temperature of the exhaust gas of the boiler can be more accurately confirmed, the exhaust temperature can be controlled stably, and the temperature of exhaust gas itself can be prevented. Even if an exhaust pipe formed of a material such as PVC is used, It is possible to prevent the exhaust pipe from being damaged due to the temperature and to prevent the exhaust gas from leaking through the damaged portion. By controlling the temperature below the reference temperature according to the exhaust gas temperature rise, It is possible to prevent the inconvenience caused by the above.

Description

[0001] The present invention relates to an exhaust gas temperature control method for a boiler,

The present invention relates to a method for controlling the temperature of an exhaust gas of a boiler, and more particularly, to a method for controlling an exhaust gas temperature of a boiler, In order to prevent the exhaust gas from leaking due to melting of the exhaust pie formed of a material such as PVC by the exhaust gas temperature through the method of making the exhaust gas temperature be lower than the limit exhaust gas temperature, The present invention relates to a method of controlling an exhaust gas temperature of a boiler,

In other words, when the exhaust pipe material of the boiler is made of PVC or the like, if the temperature of the exhaust gas is increased due to the low melting temperature of the material, the exhaust pipe may melt, resulting in leakage of the exhaust gas, To control the exhaust gas temperature of the boiler so that the exhaust pipe can be controlled at a temperature lower than the limit exhaust gas temperature based on the temperature before the exhaust pipe is melted.

Generally, a boiler is installed to supply heating and hot water. It uses heat generated by burning various fuels to heat water, directly use heated water, or to be used for heating of a home or various buildings. And it is widely developed and used not only from small boiler used for household use to large boiler used for industrial use but also classified into oil boiler and gas boiler according to the fuel used and various kinds of boilers have been developed .

Such a boiler operates the main body through a remote control or a temperature control device so as to burn oil or coal or gas as fuel and supply electricity to the heater, In the case of a domestic boiler, the hot water is supplied to the piping installed on the floor of the room for heating, or the hot water is supplied through a water pipe, etc. .

In most conventional boilers, when the temperature of the exhaust gas is checked by the temperature of the heat exchanger and the temperature of the exhaust gas, it is impossible to confirm the influence of the heat quantity. Therefore, the exhaust gas temperature rise can not be detected due to the difference in accuracy of the exhaust gas temperature calculation, Control is performed at a temperature.

Further, conventionally, when the temperature of the exhaust gas becomes equal to or higher than the reference temperature, the operation of the combustor is stopped, resulting in inconvenience to the user.

In other words, since the conventional boiler indirectly predicts the temperature of the exhaust gas by the supply and return temperature of the heat exchanger, there is no information about the heat quantity of the product, An error may occur and the exhaust pipe may be damaged due to an increase in the exhaust gas temperature. In addition, when the combustor is safely stopped in response to the rise of the exhaust gas temperature, the combustion is stopped while the user is using the boiler in the hot water or heating mode There is a problem that it gives a lot of inconvenience to the user.

In addition, if the exhaust gas temperature safety device operates at a low temperature due to a difference in precision, the boiler may be shut down even though there is no abnormality in the exhaust gas temperature. Therefore, There is also a problem such as.

Korean Patent Publication No. 3000-00435141 (July 15, 2000) Korean Patent Publication No. 10-2013-0126116 (November 20, 2013)

SUMMARY OF THE INVENTION It is an object of the present invention to solve the above problems of the related art, and it is an object of the present invention to provide an exhaust gas purifying apparatus, The temperature of exhaust gas of the boiler can be more accurately confirmed by making the temperature of the exhaust gas lower than the limit exhaust gas temperature so that the exhaust temperature can be stably controlled and the temperature of the exhaust gas itself can be prevented. It is possible to prevent the exhaust pipe from being damaged due to the high exhaust gas temperature even when the exhaust pipe formed of the material is used and also to prevent the leakage of the exhaust gas through the damaged portion, It is possible to prevent the inconvenience caused by the user from stopping the operation of the combustor during use of the boiler And to provide a method for controlling the temperature of an exhaust gas of a boiler which can significantly improve the merchantability of the boiler itself.

According to an aspect of the present invention, there is provided a method for controlling a boiler in which when a heat quantity is controlled after combustion in a heating or hot water mode, a controller sets a first set temperature (TsetS) (Tset); Confirming the controlled calorie (Q) of the current combustor; The present control quantity Q is compared with the formula defined by the slope (a) and the offset value (b) of the exhaust gas temperature dependence of the heat quantity with respect to the heat exchanger temperature Tin stored in the storage device, Calculating a boundary temperature (T1) at the water return temperature; Confirming the current water return temperature (Tin) of the heating water detected through the water return temperature detection sensor; Determining whether the current water return temperature Tin is higher than the boundary temperature T1 at the water return temperature; Determining whether the supply control temperature Tset is higher than a predetermined limited exhaust gas temperature T2 if the present return water temperature Tin is higher than the boundary temperature T1 at the return water temperature; And exhausting the combustor if the supply control temperature Tset is lower than or equal to the predetermined limit exhaust gas temperature T2.

As a result of comparison between the supply control temperature Tset and the predetermined limited exhaust gas temperature T2, it is found that the supply control temperature Tset is lower than or equal to the predetermined limited exhaust gas temperature T2, , Displaying an error state on the display device, and stopping the driving of the boiler.

If the supply control temperature Tset is higher than the predetermined limit exhaust gas temperature T2 as a result of a comparison between the supply control temperature Tset and the predetermined limited exhaust gas temperature T2 in the control device, ) By one step lower than the predetermined temperature (X); Determining again whether the supply control temperature (Tset) set lower by the predetermined temperature (X) is higher than a predetermined limit exhaust gas temperature (T2); If the supply control temperature Tset set lower by the predetermined temperature X is lower than or equal to the predetermined limit exhaust gas temperature T2, the supply control temperature Tset set lower by the predetermined temperature X is set to the limited exhaust gas temperature T2 ) Is further performed.

On the other hand, if the control unit determines that the current water temperature Tin is lower than or equal to the boundary temperature T1 at the water-return temperature as a result of a comparison between the current water temperature Tin and the boundary temperature T1 at the water- Determining whether the value of the boundary temperature (T1) - the present return water temperature (Tin) at the water return temperature is equal to or higher than a predetermined temperature difference (T3); The present supply control temperature Tset is lower than the previous set temperature TsetS stored in the storage device if the value of the boundary temperature T1 at the return water temperature and the current return water temperature Tin is equal to or higher than the predetermined temperature difference T3 Judging whether or not the image is formed; If the current supply control temperature Tset is lower than the previous set temperature TsetS stored in the storage device, setting the supply control temperature Tset one step higher by the predetermined temperature X; Determining again whether the supply control temperature (Tset) set up by the predetermined temperature (X) is lower than the previous set temperature (TsetS) stored in the storage device; If the supply control temperature Tset set up by the predetermined temperature X is higher than or equal to the previous set temperature TsetS, the supply control temperature Tset set up by the predetermined temperature X is set to the set temperature TsetS ) In the step (c).

If the supply control temperature Tset is higher than the predetermined limit exhaust gas temperature T2 or the current supply control temperature Tset is lower than the previous set temperature TsetS stored in the storage device, Or the supply control temperature Tset which is set up by changing the supply control temperature Tset which is set lower by the predetermined temperature X to the limit exhaust gas temperature T2 or by the predetermined temperature X, After the predetermined time A has elapsed after waiting for the predetermined time A until the temperature is stabilized after changing the set temperature TsetS within the set temperature TsetS, As in the case where the value Tin is less than the predetermined temperature difference T3 or the current supply control temperature Tset is higher than or equal to the previous set temperature TsetS stored in the storage device, Q) And then returns and repeats the subsequent steps.

At this time, the boundary temperature (T1) at the corresponding water return temperature is characterized by being a controlled calorie (Q) + offset value (b) of the slope (a) X current combustor.

The predetermined exhaust temperature T3 is set to 10 to 15 DEG C and the supply control temperature Tset is set to be lower than the melting temperature of the exhaust pipe at 60 to 70 DEG C, Or a predetermined temperature (X) to be upwardly set is set to "5 to 10 ° C", and a predetermined time (A), which is a temperature stabilization time, is set to "20 to 30 seconds".

As described above, according to the method for controlling the temperature of the exhaust gas of the boiler according to the present invention, if the temperature of the exhaust gas is checked in relation to the heat exchanger temperature and the heat quantity of the heat exchanger and the temperature becomes equal to or higher than the limit exhaust gas temperature The temperature of the exhaust gas is made to be lower than the exhaust gas temperature by lowering the temperature so that the temperature of the exhaust gas of the boiler can be more precisely checked and the exhaust temperature can be controlled stably and the rise of the exhaust gas temperature can be prevented, It is possible to prevent the exhaust pipe from being damaged due to the high temperature exhaust gas temperature and to prevent the exhaust gas from leaking through the damaged portion and to prevent the exhaust pipe from leaking under the reference temperature The user can avoid inconveniences caused by stopping the operation of the combustor during use of the boiler It is possible to prevent the polishing marketability of the boiler itself, of course, would be very useful inventors etc. that can greatly improve the reliability of the exhaust gas temperature control of a boiler.

1 is a schematic block diagram of a boiler to which the method of the present invention is applied;
2 is a flow chart for explaining the method of the present invention.
FIG. 3 is a graph showing an exhaust temperature relationship according to a return water temperature in a state where a supply temperature of a heat exchanger of a boiler to which the present invention is applied is fixed at a predetermined temperature (85 ° C.).
FIG. 4 is a graph showing a boundary of the exhaust gas temperature according to the relationship between the heat amount of the boiler and the heat exchanger return temperature according to the present invention.

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

In the following description of the present invention, a detailed description of known functions and configurations incorporated herein will be omitted when it may make the subject matter of the present invention rather unclear.

FIG. 1 is a schematic block diagram of a boiler to which the method of the present invention is applied. FIG. 2 is a flow chart for explaining the method of the present invention. FIG. 4 is a graph showing the relationship between the exhaust temperature and the exhaust temperature according to the relationship between the heat amount of the boiler and the heat exchanger return temperature according to the present invention. FIG.

According to the present invention,

When the boiler is controlled in the heat quantity after the combustion according to the heating or hot water mode, the control device 1 stores the initial set temperature TsetS set by the user in the storage device 12 as the supply control temperature Tset of the heat exchanger (S1);

(S2) of checking the control calorie (Q) of the current combustor;

The present control quantity Q is set to the formula defined by the slope a and the offset value b of the exhaust temperature relationship with respect to the heat exchange rate of the heat exchanger stored in the storage device 12 (S3) of calculating the boundary temperature (T1) at the return water temperature in comparison with the boundary temperature (T1);

(S4) confirming the current water return temperature (Tin) of the heating water detected through the water return temperature detection sensor (3);

Determining whether the current water temperature Tin is higher than the boundary temperature T1 at the water return temperature;

(S6) judging whether the supply control temperature (Tset) is higher than a predetermined limit exhaust gas temperature (T2) if the present return water temperature (Tin) is higher than the boundary temperature (T1) at the return water temperature;

(S7) of extinguishing the combustor if the supply control temperature Tset is lower than or equal to the predetermined restricted exhaust gas temperature T2 (No in S6).

As a result of comparison between the supply control temperature Tset and the predetermined limited exhaust gas temperature T2, it is determined that the supply control temperature Tset is lower than or equal to the predetermined limit exhaust gas temperature T2, 1)

(S8) of stopping the drive of the boiler as well as displaying an error state on the display device (71).

If the supply control temperature Tset is higher than the predetermined limit exhaust gas temperature T2 as a result of comparison between the supply control temperature Tset and the predetermined restricted exhaust gas temperature T2 in the control device 1 (Yes in S6)

Setting (S9) a supply control temperature (Tset) by one step lower by a predetermined temperature (X);

(S10) again determining whether the supply control temperature (Tset) set lower by the predetermined temperature (X) is higher than a predetermined limited exhaust gas temperature (T2);

If the supply control temperature Tset set lower by the predetermined temperature X is lower than or equal to the predetermined limit exhaust gas temperature T2 (No in S10), the supply control temperature Tset which is set down by the predetermined temperature X is set to (S11) of changing the exhaust gas temperature to the limited exhaust gas temperature (T2).

As a result of the comparison (S5) between the current water temperature Tin and the boundary temperature T1 at the water-return temperature in the controller 1, the current water-return temperature Tin is lower than the boundary temperature T1) (No in S5)

(S12) determining whether the value of the boundary temperature (T1) at the water return temperature and the current water return temperature (Tin) is equal to or higher than a predetermined temperature difference (T3);

The current supply control temperature Tset is set to the previous set temperature TsetS stored in the storage device 12 when the value of the boundary temperature T1 at the water return temperature and the current return temperature Tin is equal to or higher than the predetermined temperature difference T3, (S13);

If the present supply control temperature Tset is lower than the previous set temperature TsetS stored in the storage device 12, the step S14 of setting the supply control temperature Tset one step higher by the predetermined temperature X ;

(S15) again determining whether the supply control temperature (Tset) set up by the predetermined temperature (X) is lower than the previous set temperature (TsetS) stored in the storage device (12);

The supply control temperature Tset set up by the predetermined temperature X is set in the storage device 12 when the supply control temperature Tset set up by the predetermined temperature X is higher than or equal to the previous set temperature TsetS (S16) of storing the temperature at a temperature (TsetS).

If it is determined that the supply control temperature Tset is higher than the predetermined exhaust gas temperature T2 or the current supply control temperature Tset is higher than the predetermined exhaust gas temperature T2 (S11) of the supply control temperature Tset which is lower than the previous set temperature TsetS (Yes in S15) or set down by the predetermined temperature X to the limited exhaust gas temperature T2 Or after changing the supply control temperature Tset set up by the predetermined temperature X to the set temperature TsetS in the storage device 12 (S16)

After waiting the predetermined time (A) until the temperature becomes stable (S17)

If the value of the boundary temperature (T1) - the current return temperature (Tin) at the return temperature is less than the determined temperature difference (T3) (No at S12) or the current supply control temperature (Tset) The control is returned to the step S2 for confirming the control amount Q of the combustor at the beginning as in the case where the temperature is higher than or equal to the previous set temperature TsetS stored in the storage device 12 (No at S13) Is repeatedly performed.

At this time, the boundary temperature (T1) at the corresponding water return temperature is characterized by being a controlled calorie (Q) + offset value (b) of the slope (a) X current combustor.

The predetermined exhaust temperature T3 is set to 10 to 15 DEG C and the supply control temperature Tset is set to be lower than the melting temperature of the exhaust pipe at 60 to 70 DEG C, Or a predetermined temperature (X) to be upwardly set is set to "5 to 10 ° C", and a predetermined time (A), which is a temperature stabilization time, is set to "20 to 30 seconds".

Reference numeral 11 denotes a calculation unit provided in the control device 1, 2 denotes a supply temperature detection sensor for detecting the supply temperature of the heating water supplied to the heating pipe, 4 denotes a flame detection device, 6 is a gas supply drive device, 7 is a temperature control device, and 8 is an ignition device.

The operation and effect of the method according to the present invention will be described with reference to FIGS. 1 to 4. FIG.

First, in the boiler control apparatus 1 to which the present invention is applied, when the boiler is controlled in the heat quantity after combustion according to the heating or hot water mode, the user sets the initial set temperature TsetS (S1) to the supply control temperature (Tset) of the heat exchanger in the storage device (12) provided in itself.

Then, the control device 1 confirms the control quantity Q of the current combustor (S2) and then calculates the slope of the exhaust temperature relationship according to the amount of heat with respect to the return temperature Tin of the heat exchanger stored in the storage device 12 the boundary temperature T1 at the return water temperature is calculated (S3) by comparing the current control heat quantity Q with the formula defined by the offset value (b) and the current control heat quantity (Q).

That is, the slope (a) and the offset value (b) of the exhaust temperature relationship with respect to the heat exchanger temperature (Tin) stored in the storage device 12 as shown in the graphs shown in FIG. 3 and FIG. ) is the slope (a) formula given by × was compared to the control amount of heat (Q) + offset (offset) value, (b) the current control amount of heat (Q) at the time of heat control in the present combustor boundary temperature in the corresponding return temperature ( T1).

Thereafter, the control device 1 confirms the present water-return temperature Tin of the heating water detected through the water-return temperature sensor 3 provided on the side of the heating water inlet of the heat exchanger (S4) It is determined whether the temperature Tin is higher than the boundary temperature T1 at the return water temperature (S5).

When the control unit 1 compares the current return temperature Tin with the boundary temperature T1 at the return temperature and the current return temperature Tin is higher than the boundary temperature T1 at the return temperature, It is judged whether or not the supply control temperature Tset is higher than the predetermined limit exhaust gas temperature T2 (S6).

Here, the limited exhaust gas temperature (T2) is set at "60 to 70 ° C" in the present invention at a temperature equal to or lower than the melting temperature of the exhaust pipe molded with PVC.

As a result of comparison between the current supply control temperature Tset and the restricted exhaust gas temperature T2 set at "60 to 70 ° C", the present supply control temperature Tset is lower than the predetermined limited exhaust gas temperature T2 (NO in S6), the exhaust gas temperature in the product can not be higher than the supply temperature, so that an error or abnormality has occurred and the burner is extinguished (S7), the error state is displayed on the display device 71, (S8).

On the other hand, when the supply control temperature Tset is higher than the predetermined limit exhaust gas temperature T2 as a result of comparison between the supply control temperature Tset and the predetermined limited exhaust gas temperature T2 in the control device 1 (Yes in S6), the supply control temperature Tset is decreased by one step (S9) by the predetermined temperature X, and then the supply control temperature Tset, which is set down by the predetermined temperature X, T2) is determined again (S10).

The supply control temperature Tset which is set lower by the determined temperature X as a result of comparing the supply control temperature Tset which is set down by the determined temperature X and the predetermined limit exhaust gas temperature T2 by the mutual comparison S10, The supply control temperature Tset which is set lower by the predetermined temperature X is changed to the limited exhaust gas temperature T2 (S11) if the temperature T2 is lower than or equal to the predetermined limit exhaust gas temperature T2 (No at S10).

As a result of comparison between the current water temperature Tin and the boundary temperature T1 at the water return temperature in the controller 1 as a result of comparison between the current water temperature Tin and the boundary temperature T1 at the water temperature, T1), it is determined whether the value of the boundary temperature (T1) - the present return water temperature (Tin) at the water return temperature is equal to or higher than the predetermined temperature difference T3 (S12).

The predetermined temperature difference T3 is set to a temperature higher than the one-step up-set temperature of the supply control temperature Tset so as not to affect the melting temperature of the exhaust pipe as the supply control temperature Tset is increased as described later. When the temperature difference T3 is set to be lower than "10 DEG C ", the exhaust temperature becomes higher when the supply control temperature is set upward, and the supply control temperature is immediately set down. If the temperature difference T3 is set to be higher than "15 DEG C ", the boiler is controlled at a control temperature lower than the temperature set by the consumer despite the low exhaust temperature, So that the predetermined temperature difference T3 is set to "10 to 15 DEG C" in the present invention.

On the other hand, when the control unit 1 compares the value of the boundary temperature (T1) - the present return water temperature (Tin) at the return water temperature with the predetermined temperature difference (T3), the boundary temperature (T1) It is judged whether the current supply control temperature Tset is lower than the previous set temperature TsetS stored in the storage device 12 (S13) if the value of the present return temperature Tin is equal to or higher than the predetermined temperature difference T3.

As a result of comparing the present supply control temperature Tset with the previous set temperature TsetS stored in the storage device 12 as a result of comparison between the current supply control temperature Tset and the previous set temperature Tset stored in the storage device 12, (TsetS), the supply control temperature Tset is set up by one step (S14) by the predetermined temperature X. [

In order to prevent the abrupt temperature change and the high cut, the downward or upward setting of the temperature (X) determined at the supply control temperature (Tset) is set at "5 to 10 ° C" If the predetermined temperature (X) for lowering or increasing the temperature is set to be lower than "5 占 폚 ", the amount of heat change is small and the decrease of the exhaust temperature is delayed so that the exhaust pipe can be melted. If set, there is a possibility that a high cut may occur due to a rapid temperature change, so that the temperature is set to "5 to 10 ° C" in the present invention.

The control device 1 having the supply control temperature Tset set up by one step (S14) by the predetermined temperature X sequentially stores the supply control temperature Tset set up by the predetermined temperature X in the memory The supply control temperature Tset which is set up by the predetermined temperature X is higher than the previous set temperature TsetS The supply control temperature Tset set up by the predetermined temperature X is changed to the set temperature TsetS in the storage device 12 (S16).

If it is determined that the supply control temperature Tset is higher than the predetermined exhaust gas temperature T2 or the current supply control temperature Tset is higher than the predetermined exhaust gas temperature T2 (S11) of the supply control temperature Tset which is lower than the previous set temperature TsetS (Yes in S15) or set down by the predetermined temperature X to the limited exhaust gas temperature T2 Or after the supply control temperature Tset set up by the predetermined temperature X is changed to the set temperature TsetS in the storage device 12 (S16), the predetermined time A is set until the temperature is stabilized, (S17).

The predetermined time (A) is set to 20 to 30 seconds, which is the time required to stabilize the temperature after the supply control temperature (Tset) is changed. This is affected by the boiler's heat control system, If the set time (A) is shorter than 20 seconds, the supply control temperature must be changed again while changing the supply control temperature, The exhaust pipe may be melted in a state where the temperature of the exhaust gas is high due to a delay in response in a state where the exhaust gas temperature is high. In the present invention, the predetermined time A, which is the stabilization time, Seconds ".

On the other hand, when the predetermined time (A) elapses after the predetermined time (A) has elapsed, the controller (1) sets the value of the boundary temperature (T1) (No at S12) or when the current supply control temperature Tset is equal to or higher than the previous set temperature TsetS stored in the storage device 12 (No at S13) The process returns to step S2 of confirming the control amount Q of the control amount Q, and the subsequent steps are repeated.

As described above, in the present invention, the exhaust gas temperature is checked in relation to the heat exchange rate of the heat exchanger, and if the exhaust gas temperature is higher than the limit exhaust gas temperature (exhaust pipe melting temperature), the control temperature is lowered, The temperature of the exhaust gas of the boiler can be confirmed more accurately and the exhaust temperature can be controlled stably. Moreover, even if the exhaust pipe formed of a material such as PVC is used, It is possible to prevent the exhaust pipe from being damaged by the exhaust gas temperature of the exhaust pipe.

In addition, it is possible to prevent the exhaust gas from leaking through the damaged portion of the exhaust pipe. By controlling the reference temperature or lower according to the exhaust gas temperature rise, It is possible to greatly improve the reliability of the boiler itself according to the exhaust gas temperature control of the boiler as well as the merchantability of the boiler itself.

Although the preferred embodiments of the present invention have been described for illustrative purposes, those skilled in the art will appreciate that various modifications, additions and substitutions are possible, without departing from the scope and spirit of the invention as disclosed in the accompanying claims. Which will be apparent to those skilled in the art.

1: Control device
11: computing device 12: storage device
2: Supply temperature detection sensor
3: Water temperature sensor
4: Flame detector
5: Fan drive device
6: Gas supply drive device
7: Temperature control device 71: Display device
8: Ignition device

Claims (9)

In the boiler, if the calorific value is controlled after the combustion,
Storing the initial set temperature (TsetS) set by the user as the supply control temperature (Tset) of the heat exchanger in the storage device;
Confirming the controlled calorie (Q) of the current combustor;
The present control quantity Q is compared with the formula defined by the slope (a) and the offset value (b) of the exhaust temperature relationship with respect to the heat exchange rate relative to the heat exchange rate of the heat exchanger stored in the storage device, Calculating a boundary temperature (T1) at the water return temperature;
Confirming the current return temperature (Tin) of the heating water;
Determining whether the current return temperature Tin is higher than the boundary temperature T1;
Determining whether the supply control temperature Tset is higher than a predetermined limit exhaust gas temperature T2 if the present return water temperature Tin is higher than the boundary temperature T1;
And exhausting the combustor if the supply control temperature (Tset) is lower than or equal to the predetermined limit exhaust gas temperature (T2).
The method according to claim 1,
In the control device in which the supply control temperature Tset is equal to or lower than the predetermined limit exhaust gas temperature T2 as a result of comparison between the supply control temperature Tset and the predetermined limited exhaust gas temperature T2,
Further comprising the step of displaying an error condition on the display device and stopping the driving of the boiler.
The method according to claim 1,
If the control device compares the supply control temperature Tset with the predetermined limited exhaust gas temperature T2 and the supply control temperature Tset is higher than the predetermined limited exhaust gas temperature T2,
Setting the supply control temperature (Tset) one step lower by a predetermined temperature (X);
Determining again whether the supply control temperature (Tset) set lower by the predetermined temperature (X) is higher than a predetermined limit exhaust gas temperature (T2);
If the supply control temperature Tset set lower by the predetermined temperature X is lower than or equal to the predetermined limit exhaust gas temperature T2, the supply control temperature Tset set lower by the predetermined temperature X is set to the limited exhaust gas temperature T2 ) To the exhaust gas temperature of the boiler.
The method according to claim 1,
If the current water temperature Tin is lower than or equal to the boundary temperature T1 as a result of the comparison between the current water temperature Tin and the boundary temperature T1,
Determining whether the value of the boundary temperature (T1) - the current return temperature (Tin) is equal to or greater than a predetermined temperature difference (T3);
Determining whether the current supply control temperature Tset is lower than a previous set temperature TsetS stored in the storage device if the value of the boundary temperature T1 and the current return temperature Tin is equal to or higher than a predetermined temperature difference T3; ;
If the current supply control temperature Tset is lower than the previous set temperature TsetS stored in the storage device, setting the supply control temperature Tset one step higher by the predetermined temperature X;
Determining again whether the supply control temperature (Tset) set up by the predetermined temperature (X) is lower than the previous set temperature (TsetS) stored in the storage device;
If the supply control temperature Tset set up by the predetermined temperature X is higher than or equal to the previous set temperature TsetS, the supply control temperature Tset set up by the predetermined temperature X is set to the set temperature TsetS ) Of the exhaust gas temperature of the boiler.
The method according to claim 3 or 4,
As a result of the determination by the control device,
If the supply control temperature Tset is higher than the predetermined limit exhaust gas temperature T2 or the current supply control temperature Tset is lower than the previous set temperature TsetS stored in the storage device or the predetermined temperature X, The supply control temperature Tset which is set up by the predetermined temperature X is changed to the set temperature TsetS in the storage device after the supply control temperature Tset set to the lower limit is changed to the limited exhaust gas temperature T2 After that,
After waiting for the predetermined time (A) until the temperature becomes stable,
If the value of the boundary temperature (T1) - the current return water temperature (Tin) at the water return temperature is less than the determined temperature difference T3 or the current supply control temperature Tset is stored in the storage device when the predetermined time (A) As with the previous set temperature TsetS,
(Q) of the current combustor at the beginning, and then repeats the steps thereafter.
The method according to claim 1,
The formula for calculating the boundary temperature (T1)
Wherein the slope (a) X is a control calorie (Q) of the current combustor plus an offset value (b).
The method of claim 3,
Wherein the limited exhaust gas temperature (T2) is set to "60 to 70 DEG C" which is equal to or lower than the melting temperature of the exhaust pipe.
The method of claim 4,
And the predetermined temperature difference (T3) is set to "10 to 15 DEG C ".
The method of claim 5,
The predetermined temperature X for lowering or increasing the supply control temperature Tset is set to "5 to 10 DEG C"
And the predetermined time (A) as the temperature stabilization time is set to "20 to 30 seconds ".

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