KR102622111B1 - Drain suppression control method of combustion facilities - Google Patents

Abstract

The present invention relates to a combustion device drain suppression control method. When the supply air temperature in the combustion device is higher than the heating water temperature and the drain generation condition is met, especially in the saturated water vapor curve of the combustion device, the heating water temperature is lower than the supply air temperature and the exhaust If the temperature is determined to be higher than the heating water temperature, the fan that supplies air to create mixed gas through the supply pipe before ignition attempt is set to an abnormal state that is predetermined to be less than the normal pre-purge rotation time (or number of rotations). After operating at the prepurge rotation time (or number of revolutions), ignition is attempted with the circulation pump off. If ignition is recognized depending on whether a flame is detected, the circulation pump is immediately operated with the circulation pump turned on, but the circulation pump is switched on according to the heating water temperature. Controls the flow rate variably.
According to the present invention, when it is determined that the heating water temperature is lower than the supply air temperature and the exhaust temperature is higher than the heating water temperature in the saturated water vapor curve of the combustion device, the fan is operated at the abnormal pre-purge rotation time (or number of rotations) before ignition is attempted and then circulated. When ignition is attempted with the pump off and ignition is recognized, the circulation pump is immediately turned on. However, if the flow rate of the circulation pump is variably controlled according to the heating water temperature, the inflow of supply air with a temperature higher than the heating water temperature is reduced, thereby draining the drain. Occurrence can be suppressed.

Description

{Drain suppression control method of combustion facilities}

The present invention relates to combustion devices such as boilers or water heaters, and more specifically, to a method of controlling combustion device drain suppression.

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.

If an ignition error or misfire occurs immediately after ignition in the existing combustion device described above, the circulation pump that circulates heat sources such as heating water or hot water through the heating load or hot water supply path while performing re-ignition remains on, That is, the pumping operation is maintained.

As mentioned above, if the circulation pump continues to be pumped on without ignition, the temperature of the heating water rapidly decreases due to the direct water supplied to the combustion device or the heating return water via the heating load, and the water flows into the supply port of the combustion device. Drainage occurs when incoming air meets cold heating water or meets the heat exchanger and pipes inside the combustor through which the heating water passes.

In this way, when the temperature of the air coming into the supply port, that is, the supply air temperature, becomes higher than the heating water temperature and the drain generation condition is met, the air to create the mixed gas for combustion is conventionally supplied through the supply pipe without ignition. The operation of the air supply fan was minimized to allow air with a temperature higher than the heating water temperature to flow into the heat exchanger and piping included in the combustor of the combustion device to attempt ignition, thereby minimizing drain generation.

However, as in the conventional embodiment described above, when determining whether the drain generation condition is met by only comparing the size of the supply air temperature and the heating water temperature, ignition error occurs due to an increase in the amount of water vapor in the air sucked into the mixing chamber, and ignition occurs immediately. It has the disadvantage of not being able to solve problems such as misfire, misdischarge, and explosion ignition.

10-2000-0043540 A

The present invention is to solve the conventional problems as described above, and the purpose of the present invention is to provide heating even in the saturated water vapor curve of the combustion device, especially when the supply air temperature in the combustion device is higher than the heating water temperature and the drain generation condition is met. If it is determined that the water temperature is lower than the supply air temperature and the exhaust temperature is higher than the heating water temperature, the fan that supplies air to create mixed gas through the supply pipe until ignition is attempted is adjusted to the normal pre-purge rotation time (or rotation time). After operating with a pre-purge rotation time (or number of rotations) set in an abnormal state less than the number of seconds, ignition is attempted with the circulation pump turned off. If ignition is recognized depending on whether a flame is detected, the circulation pump is immediately operated with the on state. , to provide a combustion device drain suppression control method that variably controls the flow rate of the circulation pump according to the heating water temperature.

In order to achieve the purpose of the present invention as described above, the combustion device drain suppression control method according to the present invention is such that when a combustion request occurs in the combustion device, the supply air temperature is higher than the heating water temperature so that the drain generation condition is met, A first process of determining whether the heating water temperature is lower than the supply air temperature in the saturated water vapor curve of the device; If the drain generation condition is not met in the first process, a second process of operating the circulation pump in an on state, attempting ignition, and then determining ignition recognition based on whether or not a flame is detected; If the drain generation condition is met in the first process and the heating water temperature is determined to be lower than the supply air temperature in the saturated water vapor curve, a third process of determining whether the exhaust temperature of the combustion device is higher than the heating water temperature; And in the third process, if it is determined that the exhaust temperature is higher than the heating water temperature, the fan that supplies air to create the mixed gas through the supply pipe until ignition is attempted is set to a normal pre-purge rotation time (or rotation time). After operating with a pre-purge rotation time (or number of rotations) in an abnormal state that is less than the number), ignition is attempted with the circulation pump off. If ignition is recognized depending on whether a flame is detected, the circulation pump is immediately turned on. It operates as a fourth process of variably controlling the flow rate of the circulation pump according to the heating water temperature.

In the combustion device drain suppression control method according to the present invention, in the second process, the circulation pump is operated in the on state and the fan that supplies air to create the mixed gas through the supply pipe until ignition is attempted is operated in the normal state. It is characterized by attempting ignition with the circulation pump turned on after operating at a pre-purge rotation time (or number of rotations).

In the combustion device drain suppression control method according to the present invention, if ignition is not recognized in the second process, the fan is operated at the normal post-purge rotation time (or number of rotations) and then proceeds to the first process. It is characterized by returning to determine again whether the drain generation conditions are met.

In the combustion device drain suppression control method according to the present invention, the fourth process is characterized in that the flow rate of the circulation pump is increased in proportion to the heating water temperature.

In the combustion device drain suppression control method according to the present invention, in the fourth process, the flow rate of the circulation pump is variably controlled according to the heating water temperature, and when the heating water temperature reaches a plurality of predetermined temperatures, the value determined according to each temperature It is characterized by variable control of the flow rate of the circulation pump.

In the combustion device drain suppression control method according to the present invention, in the fourth process, if ignition is attempted with the circulation pump off and ignition is not recognized depending on whether a flame is detected, the fan is operated in a normal state post-purge. ) After operating with a predetermined abnormal state post-purge rotation time (or number of rotations) that is less than the rotation time (or number of rotations), it returns to the first process and determines again whether the drain generation conditions are met. Do it as

In the combustion device drain suppression control method according to the present invention, ignition is recognized in the second step, or a fifth step of performing heat quantity control according to the required heat amount of the combustion device following the fourth step is further included. It is characterized by

In the combustion device drain suppression control method according to the present invention, while controlling the heat amount according to the required heat amount of the combustion device in the fifth process, the extinguishing conditions of the combustion device (e.g., heating, hot water off, error detection, etc.) are controlled. It is characterized by further comprising a sixth process of extinguishing the combustor of the combustion device and returning to the first process to maintain the combustion standby state when the fire extinguishing necessary conditions) are input.

In the combustion device drain suppression control method according to the present invention, in the sixth process, when the combustor of the combustion device is extinguished, the fan is operated at a steady state post-purge rotation time (or number of rotations) and then the first It is characterized by returning to the process and maintaining the combustion standby state.

According to the present invention, when it is determined that the heating water temperature is lower than the supply air temperature and the exhaust temperature is higher than the heating water temperature in the saturated water vapor curve of the combustion device, the fan is operated at the abnormal pre-purge rotation time (or number of rotations) before ignition is attempted and then circulated. When ignition is attempted with the pump off and ignition is recognized, the circulation pump is immediately turned on. However, if the flow rate of the circulation pump is variably controlled according to the heating water temperature, the inflow of supply air with a temperature higher than the heating water temperature is reduced, thereby draining the drain. Occurrence can be suppressed.

1 is a block diagram showing an embodiment of a combustion control device for a combustion device that performs a combustion device drain suppression control method according to the present invention.
Figure 2 is a flowchart illustrating a combustor drain suppression control method according to the present invention.
Figure 3 is a graph showing drain generation conditions in which the heating water temperature is lower than the supply air temperature in the saturated water vapor curve of 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 combustor drain suppression control method 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 modifications.

Referring to FIG. 1, the combustion device drain suppression control method according to the present invention is performed by the combustion control device 100 of the combustion device (eg, 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 200 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 controls the combustion operation of the combustor 140 according to the user-set temperature during normal combustion after a combustion request is generated by the temperature controller 200.

The controller 150 operates the fan 110 at a predetermined purge rotation speed after combustion is requested by the temperature controller 200 and before combustion.

The controller 150 controls the flow rate of the circulation pump 151 during combustion operation of the combustor 140.

The controller 150 detects ignition or extinguishment depending on whether a flame is detected by the flame detection sensor 152 installed in the burner of the combustor 140.

The controller 150 monitors the change in heating water temperature during the combustion operation of the combustor 140, before the combustion operation, and after the combustion operation (extinguishment state) through the heating water temperature sensor 153 installed in the burner of the combustor 140. sense

The controller 150 operates the combustion operation of the combustor 140 through the supply air temperature sensor 154 installed in or around the air supply pipe of the combustor 140 or in the air supply system piping of the combustor 140 or around it. Detects changes in supply air temperature before and after combustion operation (extinguishing state).

The controller 150 is operated during combustion of the combustor 140 or before combustion operation through the exhaust temperature sensor 155 installed in or around the exhaust pipe of the combustor 140 or in the exhaust system piping of the combustor 140 or its vicinity. , Detects changes in exhaust temperature after combustion operation (extinguished state).

The combustion device drain suppression control method (S100) 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 (S112) in the combustion atmosphere (S111) of a combustion device to which the combustion device drain suppression control method (S100) according to the present invention is applied, such as a boiler or water heater, the controller (150) The supply air temperature is higher than the heating water temperature so that the drain generation condition is met, but the first process (S110) is performed to determine whether the heating water temperature is lower than the supply air temperature in the saturated water vapor curve of the combustion device (S113).

The saturated water vapor curve of the combustion device is displayed as a graph of changes in supply air temperature and heating water temperature, as shown in FIG. 3, corresponding to the product specifications of the combustion device.

If the drain generation condition is not met in the first process (S110), the controller 150 operates the circulation pump 151 in an on state, attempts ignition, and then recognizes ignition depending on whether a flame is detected. Perform the second determination process (S120).

For example, in the second process (S120), the circulation pump operates in an on state (S121) and the fan 110, which supplies air to create a mixed gas through the supply pipe until ignition is attempted, is operated in a steady state pre-purge (S121). Pre-purge) After operating with rotation time (or number of revolutions) (S122), ignition is attempted with the circulation pump turned on (S123).

In Figure 2, the circulation pump 151 is operated with the on state, the fan 110 is operated at a steady state pre-purge rotation time t seconds (or rotation speed 'a' Hz), and then the gas supply valve 120 is operated. This shows an embodiment in which ignition is attempted by turning on and turning on the igniter for the burner of the combustor 140.

As a result of attempting ignition in the second process (S120) as described above, if ignition is not recognized, the controller 150 sets the fan 110 to the normal post-purge rotation time (or number of rotations). After operation, the process returns to the first process (S110) and again determines whether the drain generation conditions are met.

In Figure 2, if ignition is not recognized in the second process (S120), the fan 110 is operated at a steady state pre-purge rotation time of t seconds and then returns to process S113 of the first process (S110). This shows an example of re-determining whether the drain generation conditions are met.

For reference, the controller 150 detects ignition when a flame is detected by the flame detection sensor 152 installed in the burner of the combustor 140.

On the other hand, if the drain generation condition is satisfied in the first process (S110), and as shown in FIG. 3, if the heating water temperature is determined to be lower than the supply air temperature in the saturated water vapor curve, the exhaust temperature of the combustion device is lower than the heating water temperature. Perform the third process (S130) to determine whether the temperature is higher than the temperature.

If it is determined in the third process (S130) that the exhaust temperature is higher than the heating water temperature, the controller 150 operates the fan 110 to supply air to create the mixed gas through the supply pipe before attempting ignition. After operating with a pre-determined abnormal state pre-purge rotation time (or number of rotations) that is smaller than the normal state pre-purge rotation time (or number of rotations) (S141), ignition is attempted with the circulation pump off ( S142) When ignition is recognized depending on whether a flame is detected (S143), the circulation pump 151 is immediately turned on, but the flow rate of the circulation pump 151 is variably controlled according to the heating water temperature (S144). S145) Perform the fourth process (S140).

In Figure 2, after operating the fan 110 at an abnormal pre-purge rotation time T seconds (or rotation speed 'A' Hz), the gas supply valve 120 is turned on, and the igniter for the burner of the combustor 140 is turned on. This shows an example in which ignition is attempted by turning on the (ignitor).

In this case, the controller 150 preferably increases the flow rate of the circulation pump in proportion to the heating water temperature. In particular, when the heating water temperature reaches a plurality of predetermined temperatures, the flow rate of the circulation pump is adjusted to a value determined according to each temperature. It is desirable to variably control .

Table 1 below is an example showing variable control of the flow rate of the circulation pump 151 according to changes in heating water temperature, and the heating water temperature shows the relationship of X℃ > Y℃ > Z℃.

Heating water temperature Circulation pump flow rate (strength) X℃ big Y℃ middle Z℃ cow

If, in the fourth process (S140), ignition is attempted with the circulation pump off and ignition is not recognized depending on whether a flame is detected (S143), the controller 150 returns the fan 110 to the normal post state. After operating with a predetermined abnormal state post-purge rotation time (or number of rotations) less than the purge rotation time (or number of rotations), the drain generation condition is returned to the first process (S110). Determine again whether it is satisfied or not.

In FIG. 2, if ignition is not recognized in the fourth process (S140), the fan 110 is operated at an abnormal post-purge rotation time T seconds (or rotation speed 'B' Hz) and then This shows an example of returning to step S113 of step 1 (S110) to determine again whether the drain generation condition is met.

Meanwhile, after ignition is recognized in the second process (S120) or the flow rate of the circulation pump 151 is variably controlled (S144) according to the heating water temperature in the fourth process (S140) (S145), the controller ( 150) performs the fifth process (S150) of controlling the heat quantity according to the heat quantity required for the combustion device.

For example, the controller 150 controls the amount of heat according to the amount of heat required in response to the user-set temperature through the temperature controller 200.

In the fifth process (S150), while controlling the amount of heat according to the amount of heat required for the combustion device, the fire extinguishing conditions of the combustion device (e.g., fire extinguishing conditions due to situations such as heating, hot water off, error detection, etc.) are input. When this happens, the controller 150 extinguishes the combustor 140 of the corresponding combustion device, returns to the first process S110, and performs a sixth process S160 of maintaining the combustion standby state.

In the sixth process (S160), when the combustor 140 of the combustion device is extinguished (S161), the controller 150 operates the fan 110 at the normal post-purge rotation time (or number of rotations). After operating, it returns to the first process (S110) and maintains the combustion standby state (S162).

In Figure 2, after the combustor 140 of the combustion device is extinguished (S161), the fan 110 is operated at a steady state post-purge rotation time t seconds (or rotation speed 'b' Hz). This shows an embodiment in which the combustion standby state is maintained by returning to step S111 of the first step (S110).

As can be seen from the above, according to the present invention, as shown in Figure 3, when it is determined that the heating water temperature is lower than the supply air temperature and the exhaust temperature is higher than the heating water temperature in the saturated water vapor curve of the combustion device, the fan ( 110) is operated at an abnormal pre-purge rotation time (or number of revolutions), and then ignition is attempted with the circulation pump in the off state. When ignition is recognized, the circulation pump (151) is immediately operated with the on state, but the heating water temperature is adjusted to Accordingly, by variably controlling the flow rate of the circulation pump 151, the generation of drain can be suppressed by reducing the inflow of supply air with a temperature higher than the heating water temperature.

100: combustion control device 110: fan
120: gas supply valve 130: mixing chamber
140: combustor 150: controller
151: Circulation pump 152: Flame detection sensor
153: Heating water temperature sensor 154: Supply air temperature sensor
155: exhaust temperature sensor 200: temperature controller

Claims (9)

When a combustion request occurs in the combustion device, the supply air temperature becomes higher than the heating water temperature so that the drain generation condition is met, but a first process (S110) of determining whether the heating water temperature is lower than the supply air temperature in the saturated water vapor curve of the combustion device;
If the drain generation condition is not met in the first process (S110), the circulation pump 151 is turned on, an ignition is attempted, and ignition recognition is determined based on whether a flame is detected (S120);
If the drain generation condition is met in the first process (S110) and the heating water temperature is determined to be lower than the supply air temperature in the saturated water vapor curve, a third process (S130) to determine whether the exhaust temperature of the combustion device is higher than the heating water temperature. ; and
In the third process (S130), if it is determined that the exhaust temperature is higher than the heating water temperature, the fan 110, which supplies air to create a mixed gas through the supply pipe before attempting ignition, is pre-purged in the normal state. After operating with pre-purge rotation time (or number of rotations) in an abnormal condition that is less than the rotation time (or number of rotations), ignition is attempted with the circulation pump turned off. If ignition is recognized depending on whether a flame is detected, the circulation pump (or number of rotations) is immediately activated. A fourth process (S140) of operating 151) in the on state and variably controlling the flow rate of the circulation pump 151 according to the heating water temperature;
A combustion device drain suppression control method comprising: According to claim 1, in the second process (S120), the fan (110) operates with the circulation pump on and supplies air to create the mixed gas through the supply pipe until ignition is attempted. (pre-purge) A combustion device drain suppression control method characterized by operating with rotation time (or number of rotations) and then attempting ignition with the circulation pump turned on. The method of claim 1, wherein if ignition is not recognized in the second process (S120), the fan 110 is operated at a normal post-purge rotation time (or number of revolutions) and then the first process (S110) is performed. ) A combustion device drain suppression control method characterized by returning to ) to again determine whether the drain generation conditions are met. The combustion device drain suppression control method according to claim 1, wherein in the fourth process (S140), the flow rate of the circulation pump (151) is increased in proportion to the heating water temperature. According to claim 1, in the fourth process (S140), the flow rate of the circulation pump 151 is variably controlled according to the heating water temperature, and when the heating water temperature reaches a plurality of predetermined temperatures, the flow rate is adjusted to a predetermined value according to each temperature. A combustion device drain suppression control method characterized by variably controlling the flow rate of the circulation pump (151). According to claim 1, in the fourth process (S140), if ignition is attempted with the circulation pump off and ignition is not recognized depending on whether a flame is detected, the fan 110 is operated in a normal state post-purge. After operating with a predetermined abnormal state post-purge rotation time (or number of rotations) smaller than the rotation time (or number of rotations), the system returns to the first process (S110) to determine again whether the drain generation conditions are met. A combustion device drain suppression control method characterized by: The method of claim 1, further comprising a fifth process (S150) in which ignition is recognized in the second process (S120) or heat quantity control is performed according to the required heat quantity of the combustion device following the fourth process (S140). A combustion device drain suppression control method, characterized in that: The method of claim 7, wherein in the fifth process (S150), when extinguishing conditions for the combustion device are input while controlling the amount of heat according to the amount of heat required for the combustion device, the combustor 140 of the combustion device is extinguished and the first A combustion device drain suppression control method further comprising a sixth process (S160) of returning to the process (S110) and maintaining the combustion standby state. According to claim 8, in the sixth process (S160), when the combustor 140 of the combustion device is extinguished, the fan 110 is operated at a steady state post-purge rotation time (or number of rotations) and then the combustor 140 of the combustion device is extinguished. A combustion device drain suppression control method characterized by returning to the first process (S110) and maintaining the combustion standby state.

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