KR20230163714A - Method of controlling max calorie combustion of combustion facilities - Google Patents

Abstract

The present invention relates to a method for controlling the combustion of the maximum heat amount of a combustion device. In order to determine initial ignition in a cold state where the combustor of the combustion device has cooled sufficiently and requires preheating, a predetermined cold state determination time has elapsed and the maximum heat amount requirement of the combustion device is met. When a condition (e.g., hot water use condition) occurs, the combustion heat amount is increased from the predetermined limit heat amount rather than the maximum heat amount immediately during the time to reach the preset maximum heat amount.
According to the present invention, when the maximum heat requirement (e.g., hot water use condition) occurs, the combustion heat amount is increased from a predetermined limited heat amount rather than the maximum heat amount immediately during the preset maximum heat reach time, and the combustor of the conventional combustion device is cold. In the initial ignition state, the maximum lifting of the combustor occurs, the resonance sound caused by the maximum lifting occurs as noise, and the instantaneous increase in carbon monoxide (CO) generation occurs when the maximum lifting occurs. ) It can solve all problems caused by poisoning and environmental pollution.

Description

{Method of controlling max calorie combustion of combustion facilities}

The present invention relates to combustion devices such as boilers or water heaters, and more specifically, to a method of controlling maximum calorie combustion in combustion devices.

Combustion appliances that operate heating or hot water by burning fuel such as gas or oil, such as boilers or water heaters, have combustion controllers installed in the combustion appliance body installed in a location away from the combustion appliance body (for example, a room or living room, etc.). The combustor (e.g. combustor, including burners and heat exchangers, etc.) in response to a request for control of combustion operation (e.g. heating operation or hot water operation) by the user operating the thermostat (also called room controller) and the output of a temperature control signal. It works by burning.

During initial ignition in a cold state where the combustor of the above-described combustion device has cooled sufficiently and requires preheating, the air/gas ratio of the mixed gas inside the mixing chamber temporarily increases when the density of the air supplied into the mixing chamber increases due to the low outside air temperature. Accordingly, the maximum lifting of the combustor occurs, and the resonance sound resulting from this maximum lifting occurs as noise.

In particular, as described above, when the maximum lifting of the combustor occurs during initial ignition in a cold state, carbon monoxide (CO) poisoning and environmental pollution occur due to an instantaneous increase in carbon monoxide (CO) generation.

10-2000-0043540 A

The present invention is to solve the conventional problems as described above. The purpose of the present invention is to determine initial ignition in a cold state in which the combustor of the combustion device is sufficiently cooled and requires preheating, and the predetermined cold state determination time has elapsed and the corresponding When the maximum heat requirement of the combustion device (e.g., hot water use condition) occurs, a combustion control method for the maximum heat amount of the combustion device is provided that increases the combustion heat amount from a predetermined limit heat amount rather than the maximum heat amount immediately during the time to reach the preset maximum heat amount. It is done.

In order to achieve the purpose of the present invention as described above, the method for controlling the maximum calorie combustion of a combustion device according to the present invention is to recognize the time of the fire extinguishing timer in a state in which combustion is confirmed after a combustion request occurs, so that the combustor of the combustion device is sufficiently A first process of determining whether the maximum heat requirement of the relevant combustion device (e.g., hot water use condition) has occurred when it is determined that a predetermined cold state determination time has elapsed to determine initial ignition in a cold state requiring cooling and preheating; When a maximum heat requirement (for example, a hot water use condition) occurs in the first process, a second process of immediately starting to increase the combustion heat from a predetermined limited heat amount rather than the maximum heat amount; Following the second process, a third process of calculating the amount of increase in combustion heat during the time to reach the maximum heat amount preset as the time required to rise from the limit heat amount to the maximum heat amount; A fourth process of determining whether the time to reach the maximum calorie content has elapsed following the third process; In the fourth process, if the combustor is extinguished before the time to reach the maximum heat has elapsed, the fifth process stops increasing the time to reach the maximum heat, resets it, and then re-increases the combustion heat from the limit heat amount. A sixth process of determining whether the maximum amount of calories has been reached following the fifth process; The cold state determination time has not elapsed in the first process, or the maximum heat requirement (e.g., hot water use condition) of the combustion device has not occurred even though the cold state determination time has elapsed in the first process, or If the time to reach the maximum amount of heat has elapsed in the fourth process, or the maximum amount of heat has been confirmed in the sixth process, from the first process to the sixth process, which is performed upon initial ignition in a cold state of the combustor of the relevant combustor, The seventh process of stopping maximum caloric combustion control and implementing normal caloric control; An eighth process of determining whether fire extinguishing conditions (e.g., fire extinguishing conditions due to situations such as heating, hot water off, error detection, etc.) of the relevant combustion device have been entered after the seventh process; and a ninth process of resetting the fire extinguishing timer, extinguishing the combustor, and returning to the first process when the extinguishing condition is input in the eighth process.

In the method for controlling combustion of the maximum amount of heat in a combustion device according to the present invention, in the first process, the minimum and maximum amount of heat required for the burner to stably ignite and burn is set according to the burner capacity of the combustor, and The ignition heat amount required for ignition is set between the minimum heat amount and the maximum heat amount.

In the method for controlling the maximum heat amount of combustion in a combustion device according to the present invention, in the second process, the limited heat amount is in a range that is lower than the maximum heat amount set according to the burner capacity of the corresponding combustor and higher than the ignition heat amount determined according to the burner capacity of the corresponding combustor. It is characterized by being set in .

In the method for controlling combustion of maximum heat amount in a combustion device according to the present invention, in the third process, the time to reach the maximum heat amount is set to take longer than the time required to rise from the ignition heat amount to the maximum heat amount determined according to the burner capacity of the combustor. It is characterized by

In the method for controlling the maximum caloric combustion of a combustion device according to the present invention, the increase in combustion calorific value in the third process is calculated using Equation 1 below.

In the combustion device maximum heat amount combustion control method according to the present invention, the initial limited heat amount in Equation 1 is set from a predetermined limit heat amount rather than the maximum heat amount immediately when a maximum heat requirement condition (e.g., hot water use condition) occurs in the combustion device. It is characterized in that it is set to a limiting amount of heat that starts to increase the amount of combustion heat.

In the method for controlling combustion of maximum heat amount in a combustion device according to the present invention, the time to reach the maximum heat amount in Equation 1 is set to the time elapsed immediately after starting to increase the amount of combustion heat from the time to reach the maximum heat amount to the initial limit heat amount. It is characterized by

In the method of controlling combustion of maximum heat amount in a combustion device according to the present invention, the increase in combustion heat in Equation 1 is expressed as a linear equation, and represents the change in combustion heat that increases during the time to reach the maximum heat amount and the change in time starting from the initial limited heat amount. It is characterized by calculating the current amount of calories and the amount of additional calories required to reach the maximum amount of calories.

According to the present invention, when the maximum heat requirement (e.g., hot water use condition) occurs, the combustion heat amount is increased from a predetermined limited heat amount rather than the maximum heat amount immediately during the preset maximum heat reach time, and the combustor of the conventional combustion device is cold. In the initial ignition state, the maximum lifting of the combustor occurs, the resonance sound caused by the maximum lifting occurs as noise, and the instantaneous increase in carbon monoxide (CO) generation occurs when the maximum lifting occurs. ) It can solve all problems caused by poisoning and environmental pollution.

1 is a block diagram showing an embodiment of a combustion control device for a combustion device that performs a method for controlling maximum calorie combustion of a combustion device according to the present invention.
Figure 2 is a flowchart illustrating a method for controlling maximum calorie combustion of a combustion device according to the present invention.
Figure 3 is a graph showing the change in the amount of combustion heat that increases during the time to reach the maximum heat amount when controlling the maximum heat amount of combustion in the combustion device according to the present invention.

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

The method for controlling maximum caloric combustion of a combustion device according to the present invention described below is not limited to the following examples, and can be used by anyone with ordinary knowledge in the relevant technical field without departing from the gist of the technology claimed in the claims. The technical spirit exists to the extent that it can be implemented with any changes.

Referring to FIG. 1, the method for controlling the maximum amount of heat combustion in a combustion device according to the present invention is performed by the combustion control device 100 of a combustion device (eg, a boiler or water heater, etc.).

The combustion control device 100 shown in FIG. 1 includes a fan 110, a gas supply valve 120, a mixing chamber 130, a combustor 140, and a controller 150.

The fan 110 operates at a predetermined purge rotation speed before or after combustion, supplies air to create a mixed gas to be burned in the combustor 140 during combustion through an air supply pipe, and supplies the mixed gas to the combustor. It is supplied to (140), and the exhaust gas is discharged to the outside through the exhaust pipe before, after, or during combustion.

The gas supply valve 120 supplies gas to create a mixed gas burned in the combustor 140 into the mixing chamber 130.

The mixing chamber 130 creates a mixed gas by mixing the air supplied through the air supply pipe and the gas supplied through the gas supply valve 120 at a predetermined ratio.

The combustor 140 operates to maintain the temperature of the tap water at the user-set temperature required through the temperature controller of the combustion device (eg, boiler or water heater, etc.).

The combustor 140 preferably includes a burner and a heat exchanger inside the housing.

The controller 150 controls the combustion operation of the combustor 140, and during normal combustion after a combustion request occurs, controls the combustion operation of the combustor 140 according to the user-set temperature.

The controller 150 operates the fan 110 at a predetermined purge rotation speed before combustion after a combustion request occurs.

The controller 150 detects ignition or extinguishment depending on whether a flame is detected by the flame detection sensor 151 installed in the burner of the combustor 140.

The controller 150 detects a temperature change after extinguishing the combustor 140 through the temperature sensor 152 installed in the burner of the combustor 140.

The controller 150 counts the time from immediately after extinguishing the combustion device through the internally installed fire extinguishing timer 153.

The maximum calorie combustion control method (S100) of the combustion device according to the present invention is performed as shown in FIG. 2 by the controller 150 of the combustion control device 100 of the combustion device according to the present invention configured as described above.

When a combustion request occurs for a combustion device to which the combustion device maximum heat combustion control method (S100) according to the present invention, such as a boiler or water heater, is applied, the controller 150 sets the fan to a predetermined purge rotation speed before combustion. After operation, ignition is detected when a flame is detected by the flame detection sensor 151 installed in the burner of the combustor 140, and combustion of the corresponding combustion device is confirmed.

As described above, in a state where combustion is confirmed after a combustion request occurs, the controller 150 recognizes the time of the fire extinguishing timer 153, and as a result, the combustor 140 of the corresponding combustion device is sufficiently cooled and is initially in a cold state requiring preheating. If it is determined that the predetermined cold state determination time has elapsed to determine ignition, the first process (S110) is performed to determine whether the maximum heat requirement of the combustion device (for example, hot water use condition) has occurred.

For reference, the controller 150 counts the time from immediately after extinguishing the combustion device through the internally installed fire extinguishing timer 153, and the temperature detected by the temperature sensor 152 is the reference temperature for determining the cold state. When it reaches this point, the time taken up to this point is set as the cold state judgment time when the combustor of the relevant combustion device has cooled sufficiently and preheating is necessary.

In addition, in the first process (S110), as shown in the graph of FIG. 3, the combustion device has the minimum and maximum heat amounts required for the burner to ignite and burn stably according to the burner capacity of the combustor 140. It is preferable that the ignition heat amount required for ignition is set between the minimum heat amount and the maximum heat amount.

If a maximum heat requirement (e.g., hot water use condition) occurs in the first process (S110), the controller 150 immediately starts to increase the combustion heat amount from a predetermined limit heat amount rather than the maximum heat amount. Perform the process (S120).

In the second process (S120), the limited amount of heat is lower than the maximum amount of heat set according to the burner capacity of the combustor 140, as shown in the graph of FIG. 3, and the ignition amount is determined according to the burner capacity of the combustor 140. It is desirable to set it in a range higher than the calorific value.

Following the second process 120, the controller 150 performs a third process (S130) to calculate the amount of increase in combustion heat during the time to reach the maximum heat amount, which is preset as the time required to rise from the limit heat amount to the maximum heat amount. do.

At this time, it is desirable to set the time to reach the maximum heat amount to take longer than the time required to rise from the ignition heat amount to the maximum heat amount, which is determined according to the burner capacity of the combustor 140.

For example, in the most preferred embodiment of the present invention, it is desirable to calculate the increase in combustion heat in the third process (S130) using Equation 1 above.

In Equation 1 above, the initial limit heat amount is the limit heat amount that starts to increase the combustion heat amount from a predetermined limit heat amount, not the maximum heat amount immediately when a maximum heat requirement condition (e.g., hot water use condition) occurs in the combustion device. It is desirable to set

In addition, in Equation 1 above, it is preferable that the time to reach the maximum remaining heat amount is set to the time elapsed immediately after starting to increase the combustion heat amount from the maximum heat amount arrival time to the initial limited heat amount.

In addition, in Equation 1 above, the increase in combustion heat is expressed as a linear equation, indicating the change in combustion heat that increases during the time to reach the maximum heat, and the current heat amount and maximum heat amount according to the change in time starting from the initial limited heat amount. It is advisable to calculate the amount of calories needed to achieve this.

Following the third process (130), the controller 150 performs a fourth process (S140) to determine whether the time to reach the maximum calorie content has elapsed.

If, in the fourth process (S140), the combustor is extinguished before the time to reach the maximum heat has elapsed, the controller 150 stops increasing the time to reach the maximum heat, resets the combustion heat from the limit heat amount, and Perform the fifth process (S150) to re-elevate.

For example, when the time to reach the maximum heat value is set at 30 seconds, the combustor 140 of the combustion device burns for only 20 seconds while rising from the initial limit heat amount to the maximum heat amount, and when extinguishing, the initial limit is set again for 30 seconds in the next combustion. Re-increases calories from calories to maximum calories.

Meanwhile, following the fifth process (S150), the controller 150 performs a sixth process (S160) to determine whether the maximum amount of heat has been reached.

At this time, if the maximum amount of heat is confirmed to have been reached in the sixth process (S160), the controller 150 starts after the first process (S110), which is performed upon initial ignition of the combustor 140 of the corresponding combustion device in a cold state. The maximum calorie burning control up to the 6th process (S160) is stopped and the 7th process (S170) of normal calorie control is performed.

On the other hand, even if the cold state determination time has not elapsed in the first process (S110) or the cold state determination time has elapsed in the first process (S110), the maximum heat requirement of the combustion device (e.g., hot water use) Even if the condition) does not occur or the time to reach the maximum heat amount has elapsed in the fourth process (S140), the controller 150 performs the first process performed upon initial ignition in a cold state of the combustor of the corresponding combustor. After (S110), the maximum calorie burning control up to the 6th process (S160) is stopped and the 7th process (S170) of performing normal calorie control is performed.

After the seventh process (S170) is performed as described above, the controller 150 determines whether the fire extinguishing conditions of the relevant combustion device (e.g., fire extinguishing conditions due to situations such as heating, hot water off, error detection, etc.) have been entered. Perform step 8 (S180).

If the extinguishing condition is input in the eighth process (S180), the controller 150 resets the time of the extinguishing timer 153, extinguishes the combustor 140, and performs the first process (S110). The 9th process (190) of returning to is performed.

For reference, Figure 3 is a graph showing the change in combustion heat amount that increases during the time to reach the maximum heat amount when controlling the maximum heat amount combustion of the combustion device according to the present invention.

Figure 3 illustrates the change in combustion heat amount during conventional heat amount combustion control and the change in combustion heat amount during maximum heat amount combustion control according to the present invention.

As shown in FIG. 3, in order to determine initial ignition in a cold state in which the combustor 140 of a combustion device such as a boiler or water heater has cooled sufficiently and requires preheating, a predetermined cold state determination time has elapsed and the maximum heat amount required for the combustion device is reached. When a condition (e.g., hot water use condition) occurs, according to the conventional caloric combustion control method, a section occurs where the combustion heat rapidly increases from the ignition heat of the combustor 140 to the maximum heat required for hot water use, so the combustor 140 There is a problem that the maximum lifting of (140) occurs.

In order to improve this, according to the maximum heat combustion control method according to the present invention, the combustion heat amount is increased from a predetermined limited heat amount rather than the maximum heat amount immediately during the preset maximum heat reach time, so that during initial ignition in a cold state, the corresponding combustor ( 140) can solve the problem of maximum lifting.

As can be seen from the above, according to the present invention, when a maximum heat requirement (e.g., hot water use condition) occurs, the combustion heat amount is increased from a predetermined limit heat amount rather than the maximum heat amount immediately during the preset maximum heat reach time. , the problem that the maximum lifting of the combustor occurs when the combustor of the conventional combustion device is initially ignited in a cold state, the problem that the resonance sound caused by the maximum lifting is generated as noise, and the instantaneous carbon monoxide (carbon monoxide) when the maximum lifting occurs. It is possible to solve all problems caused by carbon monoxide (CO) poisoning and environmental pollution due to increased CO) generation.

100: combustion control device 110: fan
120: gas supply valve 130: mixing chamber
140: combustor 150: controller
151: Flame detection sensor 152: Temperature sensor
153: Digestion timer

Claims (11)

As a result of recognizing the time of the fire extinguishing timer in a state where combustion is confirmed after a combustion request occurs, if the combustor of the combustion device is sufficiently cooled and it is determined that the predetermined cold state judgment time to determine initial ignition in a cold state requiring preheating has elapsed, the A first process (S110) of determining whether the maximum heat requirement of the combustion device has occurred;
When the maximum heat requirement occurs in the first process (S110), a second process (S120) of immediately starting to increase the combustion heat from a predetermined limited heat amount rather than the maximum heat amount;
Following the second process (120), a third process (S130) of calculating the increase in combustion heat during the time required to reach the maximum heat amount, which is preset as the time required to rise from the limit heat amount to the maximum heat amount;
Following the third process (130), a fourth process (S140) of determining whether the time to reach the maximum calorie content has elapsed;
In the fourth process (S140), if the combustor is extinguished before the time to reach the maximum heat has elapsed, the increase in the time to reach the maximum heat is stopped, reset, and the fifth process (S150) is to re-increase the combustion heat from the limit heat amount. ;
Following the fifth process (S150), a sixth process (S160) to determine whether the maximum amount of calories has been reached;
If the maximum amount of heat is confirmed to be reached in the sixth process (S160), the maximum amount of heat is burned from the first process (S110) to the sixth process (S160), which is performed during initial ignition in a cold state of the combustor of the combustion device. Seventh process (S170) of stopping control and implementing normal caloric control;
An eighth process (S180) to determine whether the extinguishing conditions for the relevant combustion device have been entered after the seventh process (S170); and
If the extinguishing condition is input in the eighth process (S180), a ninth process (190) of resetting the fire extinguishing timer, extinguishing the combustor, and returning to the first process (S110);
A combustion device maximum caloric combustion control method comprising: The method of claim 1, wherein in the first process (S110), the minimum and maximum heat amounts required for the burner to stably ignite and burn are set in the combustion device according to the burner capacity of the combustor, and the minimum heat amount and maximum heat amount are set. A combustion device maximum heat amount combustion control method, characterized in that the ignition heat amount required for ignition is set in the meantime. The method of claim 1, wherein in the second process (S120), the limited heat amount is set in a range that is lower than the maximum heat amount set according to the burner capacity of the corresponding combustor and higher than the ignition heat amount determined according to the burner capacity of the corresponding combustor. A method of controlling maximum caloric combustion of a combustion device. The combustion method of claim 1, wherein in the third process (S130), the time to reach the maximum heat amount is set to take longer than the time required to rise from the ignition heat amount to the maximum heat amount determined according to the burner capacity of the combustor. How to control your device's maximum calorie burn. The method of claim 1, wherein the increase in combustion heat in the third process (S130) is calculated using the following equation:

A combustion device maximum caloric combustion control method characterized by calculating. The method of claim 5, wherein the initial limit heat amount is set to a limit heat amount that starts to increase the combustion heat amount from a predetermined limit heat amount rather than the maximum heat amount immediately when a maximum heat requirement condition occurs in the combustion device. How to control calorie burning. The method of claim 5, wherein the remaining maximum heat amount reaching time is set to the time elapsed immediately after starting to increase the combustion heat amount from the maximum heat reaching time to the initial limit heat amount. The method of claim 5, wherein the increase in combustion heat is expressed in a linear equation, indicating the change in combustion heat that increases during the time to reach the maximum heat, and the current heat amount according to the change in time starting from the initial limited heat amount and the amount of heat required to reach the maximum heat amount. A method for controlling the maximum amount of heat in a combustion device, characterized by calculating the amount of heat. The method of claim 1, wherein even if the cold state determination time has not elapsed in the first process (S110), the first process (S110) is performed upon initial ignition in a cold state of the combustor of the corresponding combustor. A combustion device maximum calorie combustion control method, characterized in that the maximum calorie combustion control up to the 6th process (S160) is stopped and the normal calorie control is performed in the 7th process (S170). The method of claim 1, wherein even if the cold state determination time has elapsed in the first process (S110) and the maximum heat requirement of the combustion device does not occur, the initial ignition of the combustion device in the cold state is performed. A combustion device maximum calorie combustion control method, characterized in that the maximum calorie combustion control from the first process (S110) to the 6th process (S160) is stopped and the normal calorie control is performed in the 7th process (S170). The method of claim 1, wherein even if the time to reach the maximum heat amount elapses in the fourth process (S140), the sixth process is performed after the first process (S110), which is performed during initial ignition in a cold state of the combustor of the corresponding combustion device. A combustion device maximum calorie combustion control method, characterized in that the maximum calorie combustion control up to the process (S160) is stopped and the normal calorie control of the seventh process (S170) is performed.

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