KR101827270B1 - Heating temperature control method according to the boiler room heating supply temperature control settings - Google Patents

Abstract

The present invention relates to a method to control a heating temperature of a boiler in accordance with room heating supply control temperature setting, comprising: a step of setting a temperature difference (ΔTR) between a room heating setting temperature (TsetR) and a room temperature (Troom) as an initial heating supply control temperature (TsetW); a step of starting heating combustion; a step of performing calorie control to increase, decrease, or fixate calories by the temperature difference (ΔTR) between the room temperature (Troom) and room heating setting temperature (TsetR); a step of downwardly setting a heating supply control temperature (TsetW) as much as a predetermined temperature with respect to a previous heating supply control terminal (TsetW); a step of initializing a continuous combustion time counted up to now; and a step of performing forcible fire extinguishment with respect to the heating combustion. Accordingly, marketability of the boiler and reliability in the room heating control setting are able to be largely improved.

Description

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a method for controlling a heating temperature of a boiler,

The present invention relates to a method of controlling a heating temperature of a boiler according to an indoor heating supply control temperature setting, and more particularly, to a method of controlling a heating temperature of a boiler using a heating supply temperature sensor and a heating / The first heating supply temperature is set according to the heating set temperature and the room temperature, and the heating supply temperature is set up or down according to whether the heating return temperature has reached the indoor heating set temperature condition so as to quickly reach the indoor heating set temperature, Which is provided to supply the required amount of heat according to the heating load through the method of supplying the supply temperature suitable for the heating load of the space required for the room heating, and to control the heating water temperature in an optimal state by eliminating unnecessary loss. And a method of controlling the heating temperature of the boiler according to the setting.

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, the heating supply temperature or the heating water return temperature is set for the heating control for the room temperature, and the fixed heating temperature is used to set the indoor heating set temperature, or the heating by the difference between the indoor heating set temperature and the room temperature And the temperature of the heating water is controlled by setting the supply temperature or the heating water return temperature.

However, since the heating water temperature control method does not consider the load on the heating water temperature of the heating pipe and controls the heating water temperature, the heating speed of the heating water may be slow or the heating time itself may become long, There is a disadvantage that the temperature difference of the heating floor may occur, and also there is a problem of waste of fuel and energy supplied to the boiler due to combustion for continuous heating.

Korean Patent Registration No. 10-1018775 (Feb. 23, 2011) Korean Registered Patent No. 10-1050289 (July 12, 2011) Korean Registered Patent No. 10-0952059 (April 01, 2010)

SUMMARY OF THE INVENTION The present invention has been made to solve the above problems, and it is an object of the present invention to provide an indoor heating control system and a method of controlling the same, In order to quickly reach the indoor heating set temperature, the heating supply temperature is set up or down according to whether the heating return temperature has reached the indoor heating set temperature condition and the heating of the space requiring heating By supplying the supply temperature suitable for the load, it is possible to check the saturation state of the space requiring heating by supplying the required heat amount according to the heating load and by controlling unnecessary loss and controlling the heating water temperature in the optimal state, Sufficient heating can be performed to improve the initial heating rate But rather it is an object to avoid unnecessary to combustion provides a heating temperature control method for a boiler in accordance with the room heating supply control temperature settings that can be subjected to heating control in an optimal state.

To achieve the above object, the present invention provides a method for calculating a temperature difference (DELTA TR) between a room heating set temperature (TsetR) of a user and a room temperature (Troom) when heating operation is "on" ; Setting the calculated temperature difference DELTA TR to the initial heating supply control temperature TsetW; Repeatedly determining whether the indoor heating set temperature TsetR is higher than the current indoor temperature Troom; If the indoor heating set temperature TsetR is higher than the current room temperature Troom, the heating supply temperature Tout detected through the heating supply temperature sensor and the heating return temperature Tin detected through the heating return temperature sensor are supplied to the heating supply Determining whether the temperature is lower than the control temperature (TsetW) times the first multiple (T1); Starting the heating combustion if the heating supply temperature (Tout) and the heating water return temperature (Tin) are both lower than the heating supply control temperature (TsetW) times the first multiple (T1); The amount of heat is increased or decreased so that the heating supply control temperature TsetW set by the temperature difference DELTATR between the present room temperature Troom and the room heating set temperature TsetR becomes equal to the heating supply control temperature TsetW and the heating supply temperature Tout, Performing a calorie control for reducing or fixing the calorific value; Determining whether the heating supply temperature (Tout) is higher than or equal to the heating supply control temperature (TsetW) times the second multiple (T2); Determining whether the heating combustion time exceeds a first predetermined time (A) if the heating supply temperature (Tout) is higher than or equal to a heating supply control temperature (TsetW) times a second multiple (T2); The state where the heating return temperature Tin is higher than or equal to the indoor heating set temperature TsetR + the predetermined temperature difference T is set as the second predetermined time (A) when the first heating time (A) B) or more; The heating supply control temperature TsetW is set to be equal to or higher than the indoor heating set temperature TsetR + the predetermined temperature difference ΔT for a predetermined second time B or more, Setting the supply control temperature (TsetW) lower by a predetermined temperature (X DEG C) with respect to the supply control temperature (TsetW); Initializing the counted continuous combustion time so far; When the heating return temperature Tin is not higher than or equal to the indoor heating set temperature TsetR + the predetermined temperature difference T or is not maintained for the second predetermined time B or more, or after the continuous burning time is initialized, Determining whether the supply temperature (Tout) is higher than or equal to the heating supply control temperature (TsetW) times the third multiple (T3); And performing the forced extinguishing for the heating combustion if the heating supply temperature Tout is higher than or equal to the heating supply control temperature (TsetW) times the third multiple (T3).

When the controller determines that the heating supply temperature Tout is higher than or equal to the heating supply control temperature TsetW multiplied by the second multiple T2, the heating supply temperature Tout is lower than the heating supply control temperature TsetW ) × second time (T2), determining whether a fourth time (D) determined after the heating combustion has elapsed to stabilize the temperature of the heating pipe; The heating supply control temperature TsetW is set to a predetermined temperature TsetW relative to the previous heating supply control temperature TsetW when the fourth time D determined after the heating combustion has elapsed or the first time A in which the heating combustion time has elapsed has elapsed (X < 0 > C), and then returns to the step of initializing the counted continuous combustion time.

If the fourth time D has not elapsed or the heating supply temperature Tout is less than the heating supply control temperature TsetW × If the heating supply temperature Tout is lower than the heating supply control temperature TsetW times the third heating value T3 as a result of determining whether the indoor heating set temperature TsetR is higher than or equal to the third predetermined value T3, If the indoor heat setting temperature TsetR is higher than the current room temperature Troom, the process returns to the step of performing the heat quantity control. On the other hand, if the room heating setting TsetR is higher than the current room temperature Troom, When the temperature TsetR is lower than or equal to the current room temperature Troom, the process returns to the step of performing the forced extinguishing for the heating combustion.

When the controller determines that the heating supply temperature Tout and the heating return temperature Tin are lower than the heating supply control temperature TsetW by the first multiple T1, the heating supply temperature Tout or the heating It is determined whether or not the predetermined forced extinguishment time C elapses after the forced fire extinguishment has been carried out when the temperature Tin is higher than or equal to the value of the heating supply control temperature TsetW times the first multiple T1, The control unit returns to the step of repeatedly determining whether the indoor heating setting temperature TsetR is higher than the current indoor temperature Troom when the forced extinguishing time C elapses.

In this case, the first drainage (T1) is set to 0.7 to 1.0 as an integer for determining the ignition temperature, the second multiple (T2) is set to 0.8 to 0.9 as an integer for determining the proportional control of the heat quantity, The triple T3 is characterized by being set to 1.1 to 1.3 as an integer for determining a high cut.

The predetermined first time (A) is set to 10 to 25 minutes, and the predetermined second time (B) is a time for circulating the heating pipe 2 to 3 times in total to determine the stabilization with respect to temperature. Min, the predetermined forced extinguishment time (C) is set to 2 to 10 minutes, and the predetermined fourth time (D) is set to "10 to 20 minutes" as the waiting time for stabilizing the temperature of the heating pipe .

The predetermined temperature difference? T is set to 5 to 15 占 폚 to check whether the heating is sufficient to confirm the difference of the water-recycling temperature with respect to the set temperature, and the heating supply control temperature TsetW is set to the previous heating supply control temperature TsetW ) Is set to 5 to 10 占 폚.

As described above, according to the heating temperature control method of the boiler according to the indoor heating supply control temperature setting of the present invention, when the heating is performed according to the indoor heating supply control temperature setting, the heating supply temperature sensor and the heat- The first heating supply temperature is set according to the indoor heating set temperature and the room temperature and the heating supply temperature is set up or down according to whether the heating return temperature has reached the indoor heating set temperature condition so as to quickly reach the indoor heating set temperature By supplying the supply temperature according to the heating load of the space requiring the heating, it is possible to supply the necessary heat amount according to the heating load and to control unnecessary loss and the heating water temperature in the optimal state, Since you can check the condition, you should heat up enough Can not only enhance the initial heating rate to avoid unnecessary combustion to carry out heater control in an optimal state, so is extremely useful inventors etc. that can greatly improve the reliability of the product and the indoor heat control setting of the boiler itself.

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.

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, and FIG. 2 is a flow chart for explaining the method of the present invention.

According to the present invention,

If the heating operation is "ON" as a result of the determination by the controller 1 of the boiler,

A step S1 of calculating a temperature difference ΔTR between an indoor heating set temperature TsetR set through the user's temperature adjusting device 7 and a room temperature Troom detected through the indoor temperature detecting sensor 8 ;

Setting the calculated temperature difference DELTA TR to the initial heating supply control temperature TsetW (S2);

(S3) repeatedly determining whether the indoor heating set temperature (TsetR) is higher than the current indoor temperature (Troom);

If the indoor heating set temperature TsetR is higher than the current indoor temperature Troom, the heating supply temperature Tout detected through the heating supply temperature sensor 2 and the heating return temperature Tin) is lower than a value obtained by multiplying the heating supply control temperature (TsetW) by a first multiple (T1);

(S5) when the heating supply temperature (Tout) and the heating water return temperature (Tin) are both lower than a value obtained by multiplying the heating supply control temperature (TsetW) by a first multiple (T1);

The amount of heat is increased or decreased so that the heating supply control temperature TsetW set by the temperature difference DELTATR between the present room temperature Troom and the room heating set temperature TsetR becomes equal to the heating supply control temperature TsetW and the heating supply temperature Tout, (S6) of performing a heat quantity control for reducing or fixing the heat quantity;

(S7) judging whether the heating supply temperature (Tout) is higher than or equal to the heating supply control temperature (TsetW) multiplied by a second multiple (T2);

(S8) judging whether the heating combustion time has exceeded the first predetermined time (A) if the heating supply temperature (Tout) is higher than or equal to the heating supply control temperature (TsetW) times the second multiple (T2);

The state where the heating return temperature Tin is higher than or equal to the indoor heating set temperature TsetR + the predetermined temperature difference T is set as the second predetermined time (A) when the first heating time (A) B) or more (S9);

The heating supply control temperature TsetW is set to be equal to or higher than the indoor heating set temperature TsetR + the predetermined temperature difference ΔT for a predetermined second time B or more, (S10) lowering the supply control temperature (TsetW) by a predetermined temperature (X DEG C) with respect to the supply control temperature (TsetW);

A step S11 of initializing the counted continuous combustion time so far;

If the state in which the heating return temperature Tin is higher than or equal to the indoor heating set temperature TsetR + the predetermined temperature difference T is not continuously maintained for a second predetermined time period B or longer (No in S9) After the initialization (S11), it is determined whether or not the heating supply temperature (Tout) is higher than or equal to the heating supply control temperature (TsetW) by the third multiple (T3);

(S13) of performing forced extinguishing for heating combustion when the heating supply temperature Tout is higher than or equal to the heating supply control temperature TsetW times the third predetermined value T3.

If it is determined that the heating supply temperature Tout is higher than or equal to the heating supply control temperature TsetW times the second multiple T2 in the controller 1, If it is lower than the value obtained by the temperature (TsetW) times the second multiple (T2) (No in S7)

A step (S14) of determining whether a fourth time (D) determined after the heating combustion (S5) has elapsed for stabilizing the temperature of the heating pipe;

When the fourth time D determined after the heating combustion has elapsed (Yes in S14) or the first time A in which the heating combustion time has elapsed (Yes in S8), the heating supply control temperature TsetW is changed to the previous (S15) of setting the heating supply control temperature (TsetW) by a predetermined temperature (X DEG C) with respect to the heating supply control temperature (TsetW), and then the process returns to the step S11 of initializing the counted continuous combustion time.

If it is determined that the fourth time D has elapsed after the heating combustion in the control device 1 (S14), the fourth time D has not elapsed (No in S14) It is determined whether or not the heating supply temperature Tout is higher than or equal to the heating supply control temperature TsetW by the third multiple T3 in step S12 and the heating supply temperature Tout is lower than the heating supply control temperature TsetW by the third multiple (Step S16) to determine again whether the indoor heating set temperature TsetR is higher than the current indoor temperature Troom if the indoor heating set temperature TsetR is lower than the indoor heating set temperature TsetR If the indoor heat setting temperature TsetR is lower than or equal to the current indoor temperature Troom, the process returns to the step S6 to perform the heat quantity control if the indoor heat setting temperature TsetR is higher than the current indoor temperature Troom. On the other hand, (S13). ≪ IMAGE >

The controller 1 determines whether the heating supply temperature Tout and the heating water return temperature Tin are lower than the heating supply control temperature TsetW by the first multiple T1, If either the supply temperature Tout or the heating return temperature Tin is higher than or equal to the heating supply control temperature TsetW times the first multiple T1, After that,

It is further determined whether or not the indoor heating setting temperature TsetR is higher than the current room temperature Troom when the forced extinguishing time C elapses And the process returns to step S3 to repeat the determination.

At this time, the sizes of the first, second, and third multiples T1, T2, and T3 are set so that the second multiples T2, the first multiples T1, the third multiples T3, The first drainage (T1) is set to 0.7 to 1.0 as an integer for determining the ignition temperature, the second drainage (T2) is set to 0.8 to 0.9 as an integer for determining the proportional control of the heat quantity, And the third multiple T3 is set to 1.1 to 1.3 as an integer for determining a high cut.

The predetermined first time (A) is set to 10 to 25 minutes, and the predetermined second time (B) is a time for circulating the heating pipe 2 to 3 times in total to determine the stabilization with respect to temperature. Min, the predetermined forced extinguishment time (C) is set to 2 to 10 minutes, and the predetermined fourth time (D) is set to "10 to 20 minutes" as the waiting time for stabilizing the temperature of the heating pipe .

The predetermined temperature difference? T is set to 5 to 15 占 폚 to check whether the heating is sufficient to confirm the difference of the water-recycling temperature with respect to the set temperature, and the heating supply control temperature TsetW is set to the previous heating supply control temperature TsetW ) Is set to 5 to 10 占 폚.

Reference numerals 11 and 12 denote not only the arithmetic unit and the storage unit provided in the control unit 1, 4 a flame detecting unit, 5 a blowing fan driving unit, and 6 a gas supply driving unit.

The operation and effect of the method of the present invention having the above steps will be described as follows.

First, in the boiler control device 1 to which the method of the present invention is applied, the output signal of the temperature regulating device 7 or the like is continuously inputted. If the heating operation enters the " The indoor heat setting temperature TsetR set by the user and the indoor temperature Troom detected through the indoor temperature detecting sensor 8 are read through the controller 10 and the temperature difference ΔTR between them is calculated S1.

Subsequently, the control device 1 sets the calculated temperature difference DELTA TR to the initial heating supply control temperature TsetW (S2) and stores it in the storage device 12 of the control device 1, It is repeatedly determined whether the temperature TsetR is higher than the room temperature Troom detected through the current room temperature detecting sensor 8 (S3).

As a result of the determination, if the indoor heating set temperature TsetR becomes higher than the current indoor temperature Troom (i.e., the indoor temperature Troom becomes lower than the indoor heating set temperature TsetR of the user) The heating supply temperature Tout is detected through the heating supply temperature sensor 2 provided in the heating water supply portion of the heat exchanger and the heating water supply temperature sensor 3 installed in the heating water supply portion of the heat exchanger (Tin) is lower than a value obtained by multiplying the heating supply control temperature (ToutW) by the first multiple (T1) after the heating supply temperature (Tout) is detected and the heating return temperature It is determined whether it is lower than the heating supply control temperature (TsetW) times the first multiple (T1) (S4).

At this time, the first drainage T1 is set to be "0.7 to 1.0" as a multiple of the heating supply set temperature TsetW for determining the ignition temperature, wherein the first drainage T1 is set to be less than "0.7" The ignition is delayed and the heating performance may be deteriorated. When the first drainage T1 is set to a value exceeding 1.0, the heating supply set temperature So that unnecessary combustion is performed. Therefore, in the present invention, the first drainage T1 is set to be between 0.7 and 1.0.

On the other hand, it is determined whether the heating supply temperature Tout and the heating water return temperature Tin are both lower than the heating supply control temperature TsetW × the first multiple T1, As a result, if the heating supply temperature Tout and the heat return temperature Tin are both lower than the heating supply control temperature TsetW × the first multiple T1, the heating combustion is started (S5).

Subsequently, the amount of heat so that the heating supply control temperature TsetW, which is set by the temperature difference DELTATR between the present room temperature Troom and the room heating set temperature TsetR, (S6) is performed.

The control device 1 determines whether the current heating supply temperature Tout is higher than or equal to the heating supply control temperature TsetW times the second heating value T2 in step S7.

In this case, the second drainage T2 is set to 0.8 to 0.9 as a multiple of the heating supply set temperature for confirming the proportional control of the amount of heat, that is, the temperature close to the heating supply set temperature TsetW, If the drainage number T2 is set to be less than 0.8, the heating water temperature is stabilized before proceeding to the next step, so that the heating performance may be deteriorated before the heating supply set point temperature is reached, If the temperature is set to a multiple of "2" (T2) in excess of "0.9", there is a problem in that it is impossible to proceed to the next step when the temperature is controlled to be lower than the heating supply set temperature according to the characteristics of the heat quantity control system. And a double (T2) is set between "0.8 and 0.9 ".

It is determined whether the heating supply temperature Tout of the heating water is higher than or equal to the heating supply control temperature TsetW by a second multiple T2 in the controller 1 as described above, If the temperature Tout is equal to or higher than the value obtained by the heating supply control temperature TsetW times the second multiple T2, it is judged whether the heating combustion time so far has passed the first predetermined time A (S8) .

At this time, the predetermined first time (A) compared with the heating combustion time performed so far is set to "10 to 25 minutes" as the time to supply the heating temperature to the space to be heated. The set first predetermined time A) may change the time according to the heating setting control temperature. If this time is set to be shorter than "10 minutes", the temperature control after heating setting control temperature upward or downward setting and the temperature of the heating pipe can be safely repeated The control temperature can be set up or down, and if it is set to a time longer than "25 minutes ", there is a disadvantage that the heating setting control temperature up or down setting is delayed in accordance with the room temperature change in the space requiring heating In the present invention, the predetermined first time (A) is set to "10 to 25 minutes".

If it is determined in step S8 that the predetermined first time A has not elapsed since the heating combustion time has been performed in the control device 1 as described above, A state in which the present heat return temperature Tin is higher than or equal to a value obtained by subtracting the indoor heating set point temperature TsetR from the set value of the temperature difference ΔT is determined as a second predetermined time period B ) Or more (S9).

At this time, the determined temperature difference? T is set to "5 to 15 占 폚" as a temperature for confirming whether the heating is sufficient or not to determine the difference of the heat return temperature with respect to the heating set temperature. The determined temperature difference? If the temperature difference DELTA T is set to be lower than "5 DEG C ", the control temperature is lowered in a state where the heat recovery water temperature is low, that is, , But if it is set higher than "15 DEG C ", the heating can be unnecessarily supplied to the heating supply control temperature higher than the required heating supply control temperature at the temperature set by the consumer. To < RTI ID = 0.0 > 15 C ".

Also, the second predetermined time (B) is a time sufficient to determine the stabilization of the heating temperature by circulating the heating pipe connected to the boiler to which the present invention is applied two to three times in total, It is set to "5 ~ 15 minutes" considering the maximum number of distributors according to the maximum heating value of the boiler and the maximum length of piping per one distributor.

If the second time (B) is set to be shorter than "5 minutes", the process proceeds to the next step before the temperature of the heating water is stabilized, so that it is extinguished before reaching the heating supply set temperature, If the second time (B) is set to be too long in excess of "15 minutes ", the heating water may be excessively supplied before the digestion condition is confirmed before proceeding to the next step. 2 hours (B) is set to "5 to 15 minutes".

On the other hand, in the control device 1, the state in which the heating water return temperature Tin is higher than or equal to the indoor heating set temperature TsetR + the predetermined temperature difference? T is maintained for a predetermined second time B or more (S9), if the state in which the heating return temperature Tin is higher than or equal to the indoor heating set temperature TsetR + the predetermined temperature difference? T is continuously maintained for the second predetermined time period B or more, The control temperature TsetW is set to a value lower than the previous heating supply control temperature TsetW by a predetermined temperature X deg.

At this time, the predetermined temperature (X DEG C) which is set lower than the previous heating supply control temperature (TsetW) or set upward as described later is set to a temperature change and a high cut at the time of setting the heating supply control temperature (TsetW) If the temperature is set to be lower than "5 ° C", the change in the amount of heat is small, and the update of the optimum amount of heat according to the change in the room temperature is delayed. If the temperature is set to a high value, the high cut may occur due to a rapid temperature change. Therefore, in the present invention, the predetermined temperature (X DEG C) is set to "5 to 10 DEG C ".

After the heating supply control temperature TsetW is set to a value lower than the previous heating supply control temperature TsetW by a predetermined temperature X DEG C in S10, the control device 1 initializes the continuous combustion time counted so far S11), when the state in which the heating water return temperature Tin is higher than or equal to the indoor heating set temperature TsetR + the predetermined temperature difference T is not continuously maintained for the second predetermined time period B or more It is determined whether the heating supply temperature Tout is higher than or equal to the heating supply control temperature TsetW by the third multiple T3.

At this time, the third drainage T3 is set to a value of "1.1 to 1.3" as a multiple of the heating supply set temperature for determining the high cut. If the third drainage T3 is set to be less than 1.1, The heating performance may be deteriorated before being supplied smoothly, and if it exceeds "1.3 ", unnecessary combustion may be performed at a temperature higher than the heating supply set temperature, , The third drainage T3 is set to "1.1 to 1.3".

It is determined whether the heating supply temperature Tout is higher than or equal to the heating supply control temperature TsetW times the third heating value T3 in step S12. Is higher than or equal to a value obtained by multiplying the heating supply control temperature (TsetW) by the third multiple (T3), it is determined that the heating has been performed sufficiently as desired by the user and forced fire extinguishing for heating combustion is performed (S13).

On the other hand, when the controller 1 determines whether the heating supply temperature Tout is higher than or equal to the heating supply control temperature TsetW times the second predetermined value T2, (D) has elapsed since the heating combustion S5 for stabilizing the temperature of the heating pipe (step S7: No) if the value of the heating supply control temperature TsetW is lower than the value of the heating supply control temperature TsetW times the second multiple T2 (S14).

In this case, the predetermined fourth time (D) is set to "10 to 20 minutes" as the temperature stabilization wait time of the heating pipe. When the fourth time (D) is set to be shorter than "10 minutes" The heating supply control temperature is raised repeatedly by setting the heating supply control temperature repeatedly. In the case of setting the heating supply control temperature longer than "20 minutes ", when the temperature of the heating water does not reach the heating supply control temperature, The supply of a large amount of heat to the required space is required, but the upward setting of the heating supply control temperature is delayed and the heating performance is lowered. Therefore, in the present invention, the set fourth time period D is set to "10 to 20 minutes" will be.

In order to stabilize the temperature of the heating pipe as described above, it is determined whether the fourth time D determined after the heating combustion S5 has elapsed in the control device 1 (S14). As a result, it is determined that the fourth time D elapses (Yes in S14) or when the first time A for which the heating combustion time has elapsed (Yes in S8), the heating supply control temperature TsetW is set to the predetermined temperature X (For example, "5 to 10 ° C") (S15), and then the process returns to step S11 for initializing the counted continuous combustion time until now, and the subsequent steps are repeated.

If it is determined in step S14 that the fourth time D has elapsed after the heating combustion as described above in the control device 1, the fourth time D has not elapsed (No in step S14) It is determined whether the heating supply temperature Tout is higher than or equal to the heating supply control temperature TsetW by the third multiple T3 or not S12. As a result, the heating supply temperature Tout is lower than the heating supply control temperature TsetW × If it is lower than the value obtained by the third multiple T3 (No in S12), a step S16 is performed again to determine whether the room heating set temperature TsetR is higher than the current room temperature Troom.

If the indoor heat setting temperature TsetR is higher than the current indoor temperature Troom as a result of judging again whether the indoor heat setting temperature TsetR is higher than the current room temperature Troom The room temperature TsetR is lower than or equal to the current room temperature Troom (that is, if the room temperature Troom is lower than the room temperature Troom), the process returns to the step S6 to repeat the subsequent steps, When the set temperature TsetR has been reached, the process returns to step S13 for performing the forced extinguishing for the heating combustion, and the subsequent steps are repeated.

On the other hand, when the controller 1 determines whether the heating supply temperature Tout and the heating water return temperature Tin are lower than the heating supply control temperature TsetW by the first multiple T1, If either the supply temperature Tout or the heating return temperature Tin is higher than or equal to the heating supply control temperature TsetW times the first multiple T1, After the elapse of the forced extinguishing time C, the indoor heating set point TsetR is set to the current indoor temperature (TsetR). If the forced extinguishing time C has elapsed, Troom), the process returns to step S3 to repeatedly perform the following steps.

The forced extinguishing time C may be set to 2 to 10 minutes. The forced extinguishing time C may be set differently according to the maximum heating value of the boiler and the set temperature. If the forced extinguishing time C is set to 2 to 10 minutes, (C) is set to be shorter than "2 minutes", there is a possibility of premature digestion at the time of re-burning. However, if the forced digestion time (C) is set to be longer than "10 minutes" There is a problem in that the temperature of the space to be heated may be reduced and the heating performance may be deteriorated. In order to raise the temperature of the space requiring heating in the reheat combustion, C) is set to "2 to 10 minutes ".

As described above, according to the present invention, the required amount of heat according to the heating load is supplied, unnecessary loss is eliminated, and the temperature of the heating water can be controlled in an optimal state, so that the saturation state of the space requiring heating can be confirmed, The initial heating rate can be improved and the unnecessary combustion can be prevented and the heating control in the optimum state can be performed. Therefore, the reliability of the boiler itself and the indoor heating control setting can be greatly improved.

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: Heating supply temperature sensor
3: Heating return temperature sensor
4: Flame detector
5: Fan drive device
6: Gas supply drive device
7: Thermostat
8: Indoor temperature sensor

Claims (8)

If the heating operation of the boiler is "on &
Calculating a temperature difference DELTA TR between the indoor heating set temperature TsetR and the room temperature Troom;
Setting the calculated temperature difference DELTA TR to the initial heating supply control temperature TsetW;
Repeatedly determining whether the indoor heating set temperature TsetR is higher than the current indoor temperature Troom;
When the indoor heating set temperature TsetR is higher than the current room temperature Troom, the heating supply temperature Tout and the heat return temperature Tin are lower than the values obtained by the heating supply control temperature TsetW times the first multiple T1 Judging whether or not the image is formed;
Starting the heating combustion if the heating supply temperature (Tout) and the heating water return temperature (Tin) are both lower than the heating supply control temperature (TsetW) times the first multiple (T1);
The amount of heat is increased or decreased so that the heating supply control temperature TsetW set by the temperature difference DELTATR between the present room temperature Troom and the room heating set temperature TsetR becomes equal to the heating supply control temperature TsetW and the heating supply temperature Tout, Performing a calorie control for reducing or fixing the calorific value;
Determining whether the heating supply temperature (Tout) is higher than or equal to the heating supply control temperature (TsetW) times the second multiple (T2);
Determining whether the heating combustion time exceeds a first predetermined time (A) if the heating supply temperature (Tout) is higher than or equal to a heating supply control temperature (TsetW) times a second multiple (T2);
The state where the heating return temperature Tin is higher than or equal to the indoor heating set temperature TsetR + the predetermined temperature difference T is set as the second predetermined time (A) when the first heating time (A) B) or more;
The heating supply control temperature TsetW is set to be equal to or higher than the indoor heating set temperature TsetR + the predetermined temperature difference ΔT for a predetermined second time B or more, Setting the supply control temperature (TsetW) lower by a predetermined temperature (X DEG C) with respect to the supply control temperature (TsetW);
Initializing the counted continuous combustion time so far;
When the heating return temperature Tin is not higher than or equal to the indoor heating set temperature TsetR + the predetermined temperature difference T or is not maintained for the second predetermined time B or more, or after the continuous burning time is initialized, Determining whether the supply temperature (Tout) is higher than or equal to the heating supply control temperature (TsetW) times the third multiple (T3);
And performing forced fire extinguishing for the heating combustion if the heating supply temperature Tout is equal to or higher than a value obtained by multiplying the heating supply control temperature TsetW by a third multiple T3, A method for controlling the heating temperature of a boiler according to a setting.
The method according to claim 1,
It is determined that the heating supply temperature Tout is higher than or equal to the heating supply control temperature TsetW times the second multiple T2 and the heating supply temperature Tout is higher than the heating supply control temperature TsetW by the second multiple (T2), then,
Determining whether a fourth time (D) has elapsed after the heating combustion for stabilizing the temperature of the heating pipe;
The heating supply control temperature TsetW is set to a predetermined temperature TsetW relative to the previous heating supply control temperature TsetW when the fourth time D determined after the heating combustion has elapsed or the first time A in which the heating combustion time has elapsed has elapsed (X < 0 > C), and then returns to the step of initializing the continuous combustion time counted up to now so as to control the heating temperature of the boiler according to the indoor heating supply control temperature setting.
The method of claim 2,
When the fourth time D has not elapsed or the heating supply temperature Tout has exceeded the heating supply control temperature TsetW times the third multiple T3 as a result of the determination that the fourth time D has elapsed after the heating combustion, If the heating supply temperature Tout is lower than the heating supply control temperature TsetW times the third heating value T3,
A step of determining again whether the indoor heating set temperature TsetR is higher than the current indoor temperature Troom and if the indoor heating set temperature TsetR is higher than the current indoor temperature Troom, To increase or decrease or fix the amount of heat so that the heating supply control temperature TsetW set by the temperature difference DELTA TR between the indoor heating set temperature TsetR and the indoor heating set temperature TsetR becomes equal to the heating supply control temperature TsetW, And returns to the step of performing control. On the contrary, when the indoor heating set temperature TsetR is lower than or equal to the current indoor temperature Troom, the process returns to the step of performing forced extinguishing for the heating combustion. A method for controlling the heating temperature of a boiler according to temperature setting.
The method according to claim 1,
The heating supply temperature Tout or the heating water return temperature Tin is determined as a result of determining whether the heating supply temperature Tout and the heating water return temperature Tin are lower than the heating supply control temperature TsetW times the first multiple T1, Is equal to or higher than a value obtained by multiplying the heating supply control temperature (TsetW) by the first multiple (T1) or after the forced extinguishing has been performed,
It is further determined whether the predetermined forced extinguishment time C has elapsed. If the forced extinguishment time C elapses, it is repeatedly determined whether the indoor heat setting temperature TsetR is higher than the current room temperature Troom Wherein the heating temperature of the boiler is lower than the heating temperature of the boiler.
The method according to claim 1,
The first drainage (T1) is set to 0.7 to 1.0 as an integer for determining the ignition temperature, the second drainage (T2) is set to 0.8 to 0.9 as an integer for determining the proportional control of the heat quantity, And the third multiples T3 are set to 1.1 to 1.3 as constants for determining the high cut. The method for controlling the heating temperature of the boiler according to the indoor heating supply control temperature setting.
The method according to claim 1,
The first time (A) is set to 10 to 25 minutes, and the second time (B) is set to 5 to 15 minutes in order to determine the stabilization with respect to the temperature by circulating the entire heating pipe 2 to 3 times Setting,
Wherein the temperature difference ΔT is set to 5 to 15 ° C. as a temperature for confirming whether the heating is sufficient or not to determine a difference between the temperature of the air and the temperature of the air to be returned to the set temperature, .
The method according to any one of claims 1 to 3,
The predetermined temperature (X DEG C) for setting the heating supply control temperature (TsetW) to the previous heating supply control temperature (TsetW)
Wherein the heating temperature is set to 5 to 10 占 폚.
The method according to claim 2 or 3,
And the fourth time (D) is set to "10 to 20 minutes" as a waiting time for temperature stabilization of the heating pipe.

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