KR101094025B1 - Safety combustion controlling method for boiler - Google Patents

Abstract

The present invention relates to a safety control method for combustion control of a boiler, and more particularly, to a safety control method for combustion control of a known boiler, the method comprising: outputting a driving signal to a blower fan when a combustion permission signal is input; Outputting a current required for the blowing fan to rotate at a predetermined rotation speed A; Determining whether the rotational speed of the actual blowing fan is equal to the first predetermined rotational speed A; Judging whether the blower fan current is larger than the first lower limit (a) and smaller than the first upper limit (b) if the rotation speed of the blower fan is equal to the first predetermined rotation speed; Judging from the above, if the current flowing in the blower fan is larger than the first lower limit value (a) and smaller than the first upper limit value (b), outputting a current required to rotate the blower fan at a predetermined rotation speed (B); ; Determining whether the rotational speed of the actual blowing fan is equal to the second predetermined rotational speed (B); Judging whether the blower fan current is larger than the second lower limit value (c) and smaller than the second upper limit value (d) when the rotation speed of the blower fan is equal to the second predetermined rotation speed as the result of the determination; Determining whether the current flowing through the blower fan is greater than the second lower limit value (c) and less than the second upper limit value (d), such as an electronic valve and a salt detection sensor, a proportional valve, and a safety circuit; Outputting a current value corresponding to the number of revolutions C of the blower fan according to the amount of control heat required for actual combustion when there is no abnormality as a result of the above checking; Determining whether the rotation speed of the blowing fan is the rotation speed (C) of the blowing fan according to the amount of control heat required for actual combustion; As a result of the above determination, if the rotation speed of the blowing fan is not the rotation speed (C) of the blowing fan according to the control heat amount required for actual combustion, the previous step is repeated, and the rotation speed of the blowing fan is changed according to the control heat amount required for the actual combustion. If the same as the number (C) performing a combustion subroutine; characterized in that consisting of.

Therefore, it is possible to prevent the generation of excessive harmful gas (CO, Nox, etc.) of the exhaust gas caused by poor combustion due to the fan control abnormality, and abnormal operation by detecting the change of exhaust load (reduction and increase of air volume) for combustion in the boiler. In addition to stopping the boiler operation before CO / NOx is excessively discharged, it is possible to check whether the fan is abnormal by detecting the rotational speed of the fan and detecting the current value flowing in the fan. It is.

Boiler, Safety Combustion, Blower Fan, Rotation Speed, Current Value, Safety Stop, Combustion Permit, Combustion Execution

Description

Safety combustion controlling method for boiler

The present invention relates to a safety control method for the combustion control of the boiler, and more particularly, to determine whether there is an abnormality in the rotation speed and current value of the fan before performing the combustion control in the boiler, in the case of abnormality, the boiler is safely stopped. It prevents the generation of excessive gas (CO, Nox, etc.) of exhaust gas caused by poor combustion due to fan control error, and detects the change of exhaust load (reduction and increase of air volume) for combustion in the boiler. The boiler is stopped before CO / NOx is excessively discharged, and the invention is invented so that abnormality of the fan can be checked by detecting the rotation speed of the fan and detecting the current value flowing through the fan.

In general, a boiler uses oil, coal, and gas as fuel to burn water or heat water using combustion heat and heat generated by supplying electricity to a heater to supply hot water to various heating facilities. It refers to a facility for boiling water. In the case of a residential boiler, it is used to supply hot water to a pipe installed in the floor of a room to heat it, or to supply hot water through a water supply pipe.

On the other hand, such a boiler does not correspond to the combustion state according to the installation situation of the market, and even though it is a normal condition, an exhaust closure error occurs, causing inconvenience to consumers, and conversely, an exhaust closure error despite an abnormal condition. The reality is that combustion can worsen without detecting.

In addition, since the combustion characteristics of the boiler change depending on the installation conditions of each year, a method of detecting the presence or absence of abnormality in the combustion characteristics for detecting the rate of change between the fixed combustion reference data and the reference data (for example, in Japanese Patent Publication No. 2982063). The intervening combustion control device) may be determined to be an abnormal condition even though it is a normal condition, thereby causing a malfunction of stopping the boiler.

In other words, the boiler has a combustibility change according to the flue gas installation conditions, the limitation of the installation conditions and the combustibility can be worsened, and the combustibility is also poor combustibility for the exhaust closure (reduction of air volume), but also combustible for exhaust load reduction (increase air volume). It is not possible to monitor the exhaust load reduction.

In addition, when detecting an abnormality of the blower fan, if only the number of revolutions of the blower fan is provided, there is a shortage as an air volume monitoring device. .

However, in the conventional boiler, it is detected whether the fan reaches the target rotational speed in order to determine whether the fan is abnormal before combustion, and at this time, it is determined whether the fan indicates an abnormal current by a predetermined value. In the case of abnormality, the fan was judged to have an abnormality and a safety stop was performed.

However, in such a case, there is a problem in that the case where the current value supplied to the fan and the current indication value are different is not verified.

The present invention has been devised to solve such a conventional problem, and the fan rotation speed at that time after detecting whether a specific fan rotation speed, A, is first reached in order to determine whether the fan is abnormal before performing combustion. Detects whether the fan current value for is between the upper limit value and the lower limit value according to the reference current value, and if there is no abnormality, secondly detects whether the specific fan speed B (speed different from the fan speed A) is reached and then Detects whether the fan current value for fan rotation speed is between the upper limit value and the lower limit value according to the reference current value, and burns when there is no abnormality. Detects abnormal operation condition of the fan according to the change, but if any abnormality occurs in one of these two detection stages, it does not burn and stops safely. During combustion, it is judged whether or not the indicated fan speed is reached and whether it is between the upper limit value and the lower limit value of the fan current. It is possible to prevent the generation of excess gas (CO, Nox, etc.) of the exhaust gas generated by the exhaust gas, and to detect the change of exhaust load (reduction and increase of air volume) for combustion in the boiler, before CO / NOx is excessively discharged during abnormal operation. Safety control method for boiler combustion control that can greatly improve the reliability itself according to the combustion operation of the boiler by stopping the boiler operation and detecting the fan's abnormality by detecting the rotation speed of the fan and detecting the current value flowing through the fan. To provide.

The present invention for achieving the above object includes a blower fan and a blower fan speed detection unit, a blower fan drive unit, a blower fan current detector, a proportional electromagnetic valve, a proportional electromagnetic valve driver, a proportional electromagnetic valve current detector, a display unit and a central operation processor Fan current and proportional variation current data (reference data) according to the number of revolutions of the fan, correction data according to the exhaust closing, current correction data of the fan (correction of manufacturing deviation of the control unit), rotation speed correction data of the fan (correction of manufacturing deviation of the fan And a control method for controlling the combustion of a boiler having an EEPROM in which correction data according to installation conditions are stored, the method comprising: outputting a driving signal to a blower fan when a combustion permission signal is input; Outputting a current required to rotate the blower fan at a predetermined rotation speed A through the blower fan driver; Determining whether the rotational speed of the actual blowing fan detected by the blowing fan rotational speed detection unit is equal to the first predetermined rotational speed; Determining whether the blower fan current detected by the blower fan current detector is greater than the first lower limit (a) and smaller than the first upper limit (b) when the rotation speed of the blower fan is equal to the first predetermined rotation speed; As a result of the above determination, if the current flowing in the blower fan is larger than the first lower limit value (a) and smaller than the first upper limit value (b), the current required to rotate the blower fan at the second rotation speed (B) is determined through the blower fan drive unit. Outputting; Determining whether the rotational speed of the actual blowing fan detected by the blowing fan rotational speed detection unit is equal to the second predetermined rotational speed; Determining whether the blower fan current detected by the blower fan current detector is greater than the second lower limit c and smaller than the second upper limit d if the rotation speed of the blower fan is equal to the second predetermined rotation speed; Determining whether the current flowing through the blower fan is greater than the second lower limit value (c) and less than the second upper limit value (d), such as an electronic valve and a salt detection sensor, a proportional valve, and a safety circuit; Outputting a current value corresponding to the number of revolutions C of the blower fan according to the amount of control heat required for actual combustion when there is no abnormality as a result of the above checking; Determining whether the rotation speed of the blowing fan detected through the blowing fan rotation speed detection unit is the rotation speed (C) of the blowing fan according to the amount of control heat required for actual combustion; As a result of the above determination, if the rotation speed of the blowing fan is not the rotation speed (C) of the blowing fan according to the control heat amount required for actual combustion, the previous step is repeated, and the rotation speed of the blowing fan according to the control heat amount required for the actual combustion is performed. If the same as the number (C) performing a combustion subroutine; characterized in that consisting of.

If it is determined that the actual number of revolutions of the fan is equal to the first predetermined number of revolutions, the step of determining whether a predetermined time (m) has elapsed is further performed. The method returns to the step of outputting a current required to rotate at a predetermined rotation speed (A) by the difference, and if the predetermined time (m) has elapsed, it is determined that the blower fan is abnormal and safely stops.

In addition, as a result of determining whether the blower fan current is larger than the primary lower limit (a) and smaller than the primary upper limit (b), the current flowing in the blower fan is not greater than the primary lower limit (a) or the primary upper limit (b). If not smaller than the blower fan is characterized in that the safety stop.

In addition, if it is determined that the rotation speed of the actual blower fan is equal to the second predetermined rotation speed, the step of determining whether the predetermined time (n) has elapsed is further performed, and if the predetermined time (n) has not passed, The fan returns to the step of outputting the current required to rotate at a predetermined rotation speed (B) in the second, and if the predetermined time (n) has elapsed is characterized in that the blower fan abnormality and safety stop.

As a result of determining whether the blower fan current is larger than the secondary lower limit (c) and smaller than the secondary upper limit (d), the current flowing in the blower fan is not greater than the secondary lower limit (c) or is greater than the secondary upper limit (d). If it is not small, it is determined that the blower fan is abnormal and characterized in that the safety stop.

At this time, the elapsed time (m) (n) is characterized in that 5-10 seconds and 10-15 seconds respectively.

In addition, the upper limit (a) and the lower limit (b) for the primary current value are ± 7% of the normal current to flow when the blowing fan is driven at the rotational speed A determined as the primary, and the upper limit value for the secondary current value ( c) and the lower limit (d) are characterized in that ± 5% of the normal current to flow when the blowing fan is driven at a rotation speed (B) determined second.

On the other hand, the combustion subroutine includes the steps of calculating the amount of heat required for actual combustion; Outputting a current required for the blowing fan to rotate at a rotation speed necessary for actual combustion through the blowing fan driver; Determining whether the rotational speed of the blowing fan represents the rotational speed by the amount of heat required for actual combustion; Determining whether the blower fan current detected by the blower fan current detector is smaller than the upper limit and larger than the lower limit if the rotation speed of the blower fan is equal to the required heat; As a result of the above determination, if the current flowing in the blower fan is smaller than the upper limit value and larger than the lower limit value, the process returns to the step of calculating the necessary recess again.

Further, as a result of determining whether the number of revolutions of the blower fan indicates the number of revolutions for actual combustion, if the number of revolutions of the blower fan is not equal to the required amount of heat, determining whether or not the predetermined time (l) has elapsed. If the time (l) has not elapsed, the blower fan returns to the step of outputting the current required to rotate at the rotational speed required for the actual combustion, and if the predetermined time (l) has elapsed, it is characterized in that the safety stop.

At this time, the elapsed time (l) is characterized in that less than 5 seconds.

In the above, the upper and lower limits for the current value of the blowing fan during combustion is characterized in that 5-10% of the calorie reference value.

As described above, according to the present invention, the fan current value with respect to the fan rotation speed at that time after detecting whether a specific fan rotation speed A is first reached in order to determine whether the fan is abnormal before performing combustion in the boiler. Detects whether the value is between the upper limit value and the lower limit value according to the reference current value, and if there is no abnormality, detects whether the specific fan speed B (rotation speed different from the fan speed A) is reached secondly and then the fan speed at that time It detects whether the fan current value is between the upper limit value and the lower limit value according to the reference current value and burns when there is no abnormality. The system detects abnormal operation status of the fan according to the change), but if any abnormality occurs in one of these two detection stages, it does not burn and does not stop safely. In addition, during combustion, it is judged whether or not the indicated fan rotation speed is reached and whether it is between the upper limit value and the lower limit value of the fan current for the fan rotation speed. Can prevent the generation of excess gas (CO, Nox, etc.) of the exhaust gas caused by poor combustion, and detects the change of exhaust load (reduction and increase of air volume) for combustion in the boiler, and the CO / NOx is excessive during abnormal operation. It is a very useful invention that can stop the operation of the boiler before it is discharged and check whether the fan is abnormal by detecting the rotation speed of the fan and detecting the current value flowing in the fan, which can greatly improve the reliability itself according to the combustion operation of the boiler. .

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

1 is a schematic block diagram of a boiler control unit to which the present invention method is applied, FIG. 2 is a graph for detecting fan fan speed and current, and FIG. 3 is a main flowchart for explaining the present invention method. 4 is a flowchart of the combustion subroutine of FIG. 3.

Accordingly, the method of the present invention is as shown in Figs. 1, 3 and 4, the blowing fan 1, the blowing fan rotation speed detection unit 2, the blowing fan drive unit 3, the blowing fan current detection unit 4, Fan current and proportional current data according to the number of revolutions of the fan, including the proportional solenoid 8, the proportional solenoid driving unit 9, the proportional solenoid current detecting unit 10, the display unit 6, and the central processing unit 7 Data), the correction data according to the exhaust closing, the current correction data of the fan (correction of manufacturing deviation of the control unit), the rotation speed correction data of the fan (correction of manufacturing deviation of the fan), and the correction data according to the installation conditions (5) In the safety control method for the combustion control of the boiler with

Outputting a driving signal to the blowing fan 1 when a combustion permission signal is input (S1);

Outputting a current required for the blowing fan 1 to rotate at a predetermined rotation speed A through the blowing fan driving unit 3 (S2);

Determining whether the actual rotation speed of the actual blowing fan 1 detected by the blowing fan rotation speed detection unit 2 is equal to the first predetermined rotation speed A;

As a result of the above determination, if the rotation speed of the blower fan 1 is equal to the first predetermined rotation speed A, the blower fan current detected by the blower fan current detector 4 is larger than the first lower limit value a and the first upper limit value b. Determining whether it is smaller than (S4);

As a result of the above determination, if the current flowing in the blower fan 1 is greater than the primary lower limit (a) and smaller than the primary upper limit (b), the blower fan 1 is set at a secondary speed through the blower fan drive unit 3. Outputting a current required to rotate to (B) (S5);

Determining whether the rotational speed of the actual blowing fan 1 detected by the blowing fan rotational speed detection unit 2 is equal to the second predetermined rotational speed B (S6);

As a result of the above determination, if the rotation speed of the blowing fan 1 is equal to the second predetermined rotation speed B, the blowing fan current detected by the blowing fan current detection unit 4 is larger than the secondary lower limit value c and the secondary upper limit value d Determining whether it is smaller than (S7);

As a result of the above determination, if the current flowing in the blower fan 1 is larger than the secondary lower limit (c) and smaller than the secondary upper limit (d), the step of checking whether there is an abnormality on the electronic valve, the salt detection sensor, the proportional valve, and the safety circuit. (S8);

Outputting a current value corresponding to the number of revolutions C of the blower fan 1 according to the amount of control heat required for actual combustion when there is no abnormality as a result of the above checking (S9);

Determining whether the rotation speed of the blowing fan 1 detected by the blowing fan rotation speed detection unit 2 is the rotation speed C of the blowing fan according to the amount of control heat required for actual combustion (S10);

As a result of the above determination, if the rotation speed of the blowing fan 1 is not the rotation speed C of the blowing fan according to the amount of control heat required for the actual combustion, the previous step S9 is repeated and the rotation speed of the blowing fan 1 is applied to the actual combustion. If the same as the rotational speed (C) of the blower fan according to the required control heat amount, performing the combustion execution subroutine (S11); characterized in that consisting of.

If it is not the same as the result of determining whether the rotational speed of the actual blower fan 1 is equal to the first predetermined rotational speed (A) (S3), it is further determined to determine whether the predetermined time (m) has elapsed (S12). If the time (m) has not elapsed, the blower fan 1 returns to the step S2 of outputting a current required to rotate at a predetermined rotation speed A, and if the predetermined time (m) has elapsed, the blower fan Judging by the abnormality of (1) and characterized in that the step (S13) to perform a safety stop.

In addition, as a result of determining whether the blower fan current is larger than the primary lower limit value (a) and smaller than the primary upper limit value (b) (S4), the current flowing in the blower fan 1 is not larger than the primary lower limit value (a). Or if it is not less than the first upper limit (b) it is characterized in that the step of determining the abnormality of the blowing fan (1) and safety stop (S13).

In addition, if it is determined that the rotation speed of the actual blower fan 1 is equal to the second predetermined rotation speed (B) (S6), it is further determined whether the predetermined time (n) has elapsed (S14). If the predetermined time (n) has not elapsed, the blower fan 1 returns to the step (S5) of outputting a current required to rotate at a predetermined rotation speed (B), and if the predetermined time (n) has elapsed, It is characterized in that the step (S15) of determining the abnormality of the blowing fan (1) and performing a safety stop.

In addition, as a result of determining whether the blower fan current is larger than the secondary lower limit value c and smaller than the secondary upper limit value d, the current flowing in the blower fan 1 is not greater than the secondary lower limit value c. If it is not smaller than the secondary upper limit (d) it is characterized in that the step of determining the abnormality of the blowing fan (1) and the safety stop (S15).

At this time, the elapsed time (m) (n) determined in each of the step (S12) (S14) is characterized in that 5-10 seconds and 10-15 seconds respectively.

In addition, the upper limit (a) and the lower limit (b) with respect to the primary current value are ± 7% of the normal current to flow when the blower fan 1 is driven at the rotational speed A determined as the primary, and the secondary current value is The upper limit (c) and the lower limit (d) are characterized in that ± 5% of the normal current to flow when the blowing fan is driven at a rotation speed (B) determined as the secondary.

On the other hand, the combustion subroutine (S11),

Calculating calories required for actual combustion (S111);

Outputting a current necessary for the blowing fan 1 to rotate at a rotational speed necessary for actual combustion through the blowing fan driver 3 (S112);

Determining whether the rotation speed of the blowing fan 1 represents the rotation speed by the amount of heat required for actual combustion (S113);

Determining whether the blower fan current detected by the blower fan current detector 4 is smaller than the upper limit and larger than the lower limit if the rotation speed of the blower fan 1 is equal to the required heat amount (S114);

As a result of the above determination, if the current flowing in the current blowing fan 1 is smaller than the upper limit and larger than the lower limit, the process returns to the initial stage (S111), and if the current flowing in the current blowing fan is not larger than the upper limit or smaller than the lower limit, the step of safe stopping. (S115); characterized in that consisting of.

In addition, as a result of determining whether the rotational speed of the blower fan 1 represents the rotational speed by the amount of heat required for actual combustion (S113), if the rotational speed of the blower fan is not equal to the required heat amount, it is determined whether a predetermined time (l) has elapsed. If the predetermined time (l) has not elapsed by performing the step (S116), the flow returns to the step (S112) for outputting a current required for the fan to rotate at the rotational speed required for the actual combustion, and the predetermined time (l). When the elapsed time has passed, it is characterized in that the step S117 is performed to safely stop and display the display unit 6 that there is an abnormality in the blowing fan 1.

At this time, the elapsed time (l) is characterized in that less than 5 seconds.

In the above, the upper and lower limits for the current value of the blower fan 1 during combustion are characterized in that the management of 5-10% of the calorie reference value.

Referring to the effect of the safety control method in the combustion control of the boiler of the present invention made as described above are as follows.

First, the control unit of the boiler to which the method of the present invention is applied, as shown in FIG. 1, the blower fan 1, the blower fan speed detector 2, the blower fan driver 3, the blower fan current detector 4, and the proportional electronic valve 8. ), A proportional solenoid drive unit (9), a proportional solenoid current detector (10), a display unit (6), a central processing unit (7), and an EEPROM (5). Fan current and proportional variable current data (reference data), correction data for exhaust closure, fan current correction data (control deviation deviation of the control unit), fan rotation speed correction data (fan deviation deviation) and installation conditions The correction data and the like are stored.

When the combustion permission request signal is input due to the user's selection of the heating or hot water mode as a result of judging by the central processing unit 7 of the boiler having the control unit having the configuration as described above, the blowing fan driving unit 3 is provided with the blowing fan driving unit 3. The driving signal is output to (S1).

Subsequently, in the central processing unit 7, the blowing fan 1 is firstly set by the blowing fan driving unit 3 (A; for example, in the case of a boiler of 20,000 kcal / h, the rotation speed A of the blowing fan). 3,000rpm ± 150rpm to output the current (for example 300mA) required to rotate (S2).

Subsequently, the central processing unit 7 receives the actual rotational speed of the blowing fan 1 through the blowing fan rotational speed detection unit 2 and the rotational speed A of which the actual rotational speed of the current blowing fan 1 is primarily determined. It is determined whether or not it is the same (S3), and as a result, if the actual rotation speed of the blowing fan 1 is not equal to the first predetermined rotation speed A, it is determined whether a predetermined time (m; for example, 5-10 seconds) has elapsed (S12). )

As a result, if the predetermined time (m) has not elapsed, the blower fan 1 returns to the step (S2) of outputting a current required to rotate at the first predetermined rotation speed (A), and the predetermined time (m) has elapsed. If it is determined that the blower fan (1) is abnormal and by making a safety stop (S13) it is possible to prevent the generation of harmful gas excess (CO, Nox, etc.) of the exhaust gas caused by poor combustion due to the fan control abnormality.

However, if the actual rotation speed of the blower fan 1 is equal to the first predetermined rotation speed A, as determined by the above, it is recognized that there is no abnormality at the first predetermined rotation speed A and the blower fan current detection unit 4 It is determined whether the blower fan current detected is greater than the first lower limit (a; for example, 300 mA-7%) and smaller than the first upper limit (b; for example, 300 mA + 7%) (S4).

As a result, if the current flowing in the blower fan 1 is not greater than the primary lower limit (a) or less than the primary upper limit (b), the blower fan 1 is determined to be abnormal and the safety stop is performed as described above. (S13).
In this case, when the current flowing in the blower fan 1 is equal to the first lower limit value a or the first upper limit value b, it is determined that the blower fan 1 is abnormal and is safely stopped.

However, as a result of the above determination, if the current flowing in the blower fan 1 is larger than the primary lower limit (a) and smaller than the primary upper limit (b), the blower fan 1 is determined to be secondary by the blower fan driver 3. Rotation speed (B; for example, in the case of a boiler of 20,000 kcal / h, the rotation speed (B) of the blowing fan outputs a current (for example, 700 mA) required to rotate at 4,500 rpm ± 150 rpm) (S5).

Subsequently, the central processing unit 7 receives the actual rotational speed of the blowing fan 1 through the blowing fan rotational speed detection unit 2, and the actual rotational speed of the current blowing fan 1 is determined by the second rotational speed B. It is determined whether or not it is the same (S6), and as a result, if the actual rotation speed of the blowing fan 1 is not equal to the second predetermined rotation speed B, it is determined whether a predetermined time (n; for example, 10-15 seconds) has elapsed (S14). )

As a result, if the predetermined time n has not elapsed, the flow returns to step S5 of outputting a current required for the blowing fan 1 to rotate at the predetermined rotation speed B as the secondary, and the predetermined time n has elapsed. If it is determined that the blower fan (1) is abnormal and by stopping the safety stop (S15) it is possible to prevent the generation of harmful gas excess (CO, Nox, etc.) of the exhaust gas caused by poor combustion due to the fan control abnormality.

However, if the actual rotation speed of the blower fan 1 is equal to the second predetermined rotation speed B as determined by the above, it is recognized that there is no abnormality at the second predetermined rotation speed B, and the blower fan current detection unit 4 It is determined whether the blower fan current detected is greater than the secondary lower limit (c; for example, 700 mA-5%) and smaller than the secondary upper limit (d; for example, 700 mA + 5%) (S7).

As a result, if the current flowing in the blower fan 1 is not larger than the secondary lower limit c or less than the secondary upper limit d, the blower fan 1 is determined to be abnormal and the safety stop is made as described above. (S15).
Here too, when the current flowing in the blower fan 1 is equal to the secondary lower limit c or equal to the secondary upper limit d, it is determined that the blower fan 1 is abnormal and is safely stopped.

As described above, in the present invention, the state of the blowing fan 1 is detected two times to detect an abnormality of the blowing fan and an abnormal operation state of the fan according to the change of the load, but when at least one of these two detection steps occurs, By stopping safety without performing combustion, it is possible to completely prevent the generation of excess gas (CO, Nox, etc.) of the exhaust gas caused by poor combustion due to an abnormal fan control.

However, as a result of the above determination, if the current flowing in the blower fan 1 is larger than the secondary lower limit value (c) and smaller than the secondary upper limit value (d), the presence or absence of an abnormality on the electromagnetic valve, the salt detection sensor, the proportional valve, and the safety circuit is confirmed. If there is no abnormality in all of the results (S8), the current value corresponding to the rotation speed C of the blowing fan 1 according to the amount of control heat required for actual combustion is output (S9).

Thereafter, the central processing unit 7 determines whether the rotation speed of the blowing fan 1 detected by the blowing fan rotation speed detection unit 2 is the rotation speed C of the blowing fan according to the amount of control heat required for actual combustion; S10), and as a result, if the rotation speed of the blowing fan 1 is not the rotation speed C of the blowing fan according to the amount of control heat required for actual combustion, the previous step S9 is repeated, but the rotation speed of the blowing fan 1 is actually If it is equal to the number of revolutions (C) of the blowing fan according to the amount of control heat required for combustion, the combustion execution subroutine (S11) is performed.

At this time, the rotation speed (C) of the blowing fan according to the amount of control heat required for actual combustion, including the first and second rotation speeds (A) (B) and the fan current value of the blower fan 1, which are some examples described above, The present invention is not limited thereto, and all of them may be changed depending on the capacity of the heat exchanger.

In addition, the reason why the elapsed time m (n) determined in said step S12 (S14) was set to 5-10 second and 10-15 second, respectively, is because the rotation speed of the blowing fan 1 is (A) or ( When the current required to rotate in B) is output, it is to accurately determine whether there is an abnormality in the state that the blower fan can be operated for a sufficient time at the current, and the elapsed time (m) (n) is an experiment. It is set by, but is not limited to this.

On the other hand, if it is determined that there is no abnormality in the blow fan before the combustion is carried out through the above steps, the central processing unit 7 performs the combustion execution subroutine (S11) shown in FIG. do.

That is, the central processing unit 7 calculates the amount of heat required for actual combustion (S111), and then outputs a current required for the blower fan 1 to rotate at a rotational speed necessary for actual combustion through the blower fan driver 3 ( Next, it is determined whether the rotational speed of the blowing fan 1 detected through the blowing fan rotational speed detection unit 2 represents the rotational speed by the amount of heat required for actual combustion (S113).

As a result, if the number of revolutions of the blower fan 1 is not equal to the required calorific value, step S116 of determining whether a predetermined time (l; for example, within 5 seconds) has elapsed is further performed. If it has not elapsed, the blower fan 1 returns to the step S112 for outputting a current required to rotate at the rotational speed required for actual combustion, and if the predetermined time ℓ has elapsed, there is an abnormality in the blower fan 1. In addition to the display zoom on the display unit 6, the boiler is given a safety stop (S117).

At this time, the reason why the predetermined time (l) determined in the step (S116) is set to within 5 seconds, when the number of revolutions of the blower fan 1 outputs the current required to rotate to the required amount of heat, the current to the blower fan In order to accurately determine whether there is an abnormality in a state that can be operated for a sufficient time in the predetermined time (l) is set by the experiment is not limited thereto.

However, as a result of the determination (S113), if the rotation speed of the blower fan 1 is equal to the required heat amount, it is determined whether the blower fan current detected by the blower fan current detector 4 is smaller than the upper limit and larger than the lower limit (S114). If the current flowing in the blowing fan 1 is smaller than the upper limit and larger than the lower limit, the flow returns to the initial stage (S111), and it is determined whether the detected blowing fan current is smaller than the upper limit and larger than the lower limit (S114). If the current flowing in is not larger than the upper limit or smaller than the lower limit, the blower fan 1 recognizes that an abnormality has occurred and displays it on the display unit 6 as well as allowing the boiler to stop safety (S115).
If the current flowing in the blower fan 1 is equal to the lower limit value or the upper limit value, it is determined that the blower fan 1 is abnormal and the safety stop is made.

As described above, according to the present invention, when the combustion of the boiler detects a change in exhaust load (a decrease and increase in air volume), the boiler can be stopped before the CO / NOx is excessively discharged during abnormal operation.

At this time, the upper and lower limits for the current value of the blower fan 1 during the combustion of the boiler was to be managed within the range of 5-10% of the calorie reference value.

As described above, according to the present invention, the abnormality of the blower fan 1 during combustion can be checked by detecting the rotational speed of the fan and detecting the current value flowing through the fan, and continuous combustion or safety stop can be performed. It can greatly improve itself.

It should be understood by those skilled in the art that various changes in form and details may be made therein without departing from the spirit and scope of the invention as defined in the appended claims.

1 is a schematic block diagram of a boiler control unit to which the present invention method is applied;

Figure 2 is a graph for the blow fan rotation speed and current detection.

3 is a main flowchart for explaining the method of the present invention.

4 is a flow chart for the combustion subroutine of FIG.

Explanation of symbols on the main parts of the drawings

1 blower fan 2 blower fan speed detection unit

3: blower fan drive unit 4: blower fan current detector

5: EEPROM 6: Display

7: central processing unit 8: proportional electronic valve

9: proportional solenoid drive unit 10: proportional solenoid current detector

Claims (10)

In the safety control method for the combustion control of the boiler equipped with the fan and the fan fan speed detection unit, the fan fan drive unit, the fan fan current detector, the proportional electromagnetic valve, the proportional electromagnetic valve driver, the proportional electromagnetic valve current detector, the display unit, the EEPROM and the central processing unit. , Outputting a driving signal to a blowing fan when a combustion permission signal is input; Outputting a current required for the blowing fan to rotate at a predetermined rotation speed A; Determining whether the rotational speed of the actual blowing fan is equal to the first predetermined rotational speed A; Judging whether the blower fan current is larger than the first lower limit (a) and smaller than the first upper limit (b) if the rotation speed of the blower fan is equal to the first predetermined rotation speed; Judging from the above, if the current flowing in the blower fan is larger than the first lower limit value (a) and smaller than the first upper limit value (b), outputting a current required to rotate the blower fan at a predetermined rotation speed (B); ; Determining whether the rotational speed of the actual blowing fan is equal to the second predetermined rotational speed (B); Judging whether the blower fan current is larger than the second lower limit value (c) and smaller than the second upper limit value (d) when the rotation speed of the blower fan is equal to the second predetermined rotation speed as the result of the determination; Determining whether the current flowing through the blower fan is greater than the second lower limit value (c) and less than the second upper limit value (d), the abnormality of the electronic valve, the salt detection sensor, the proportional valve, and the safety circuit; Outputting a current value corresponding to the number of revolutions C of the blower fan according to the amount of control heat required for actual combustion when there is no abnormality as a result of the above checking; Determining whether the rotation speed of the blowing fan is the rotation speed (C) of the blowing fan according to the amount of control heat required for actual combustion; As a result of the above determination, if the rotation speed of the blowing fan is not the rotation speed (C) of the blowing fan according to the control heat amount required for actual combustion, the previous step is repeated, and the rotation speed of the blowing fan according to the control heat amount required for the actual combustion is performed. If the same as the number (C) performing a combustion execution subroutine; blowing fan speed correction method for the safe combustion of the boiler comprising a. The method according to claim 1, The EEPROM includes fan current and proportional variation current data (reference data) according to the rotational speed of the fan, correction data according to exhaust closure, current correction data of the fan (correction of manufacturing deviation of the control unit), and rotational speed correction data of the fan (B) manufacturing deviation correction) and correction data according to installation conditions are stored in the fan fan speed correction method for safe combustion of a boiler. The method according to claim 1, If it is not determined that the actual rotation speed of the blowing fan is equal to the first predetermined rotation speed (A), the step of determining whether the predetermined time (m) has elapsed is further performed. Returning to the step of outputting the current required to rotate at the first predetermined rotation speed (A), and if the predetermined time (m) has elapsed, it is determined that the blower fan is abnormal and the safety combustion of the boiler characterized in that the safety stop. Blow fan rotation speed correction method. The method according to claim 1, It is determined whether the blower fan current is greater than the primary lower limit (a) and less than the primary upper limit (b). If the current flowing in the blower fan is not greater than the primary lower limit (a) or less than the primary upper limit (b), Blow fan rotation speed correction method for the safe combustion of the boiler, characterized in that for determining the safety of the fan and stop. The method according to claim 1, If it is not determined that the actual rotation speed of the blowing fan is equal to the second predetermined rotation speed (B), the step of determining whether the predetermined time (n) has elapsed is further performed, and if the predetermined time (n) has not elapsed, Returning to the step of outputting the current required to rotate at the second predetermined rotation speed (B), and if the predetermined time (n) has elapsed, it is determined that the blower fan is abnormal and the safety combustion of the boiler characterized in that the safety stop. Blow fan rotation speed correction method. The method according to claim 1, It is determined whether the blower fan current is greater than the secondary lower limit (c) and less than the secondary upper limit (d). If the current flowing in the blower fan is not greater than the secondary lower limit (c) or less than the secondary upper limit (d). Blow fan rotation speed correction method for the safe combustion of the boiler, characterized in that the blow fan is determined to be abnormal. The method according to claim 1, The upper limit (a) and the lower limit (b) for the primary current value are ± 7% of the normal current to flow when the blowing fan is driven at the rotational speed (A) determined as the primary, and the upper limit (c) for the secondary current value. And a lower limit (d) is ± 5% of a normal current value to be flown when the blowing fan is driven at a predetermined rotation speed (B). The method according to claim 1, The combustion subroutine, Calculating calories required for actual combustion; Outputting a current required for the blowing fan to rotate at a rotational speed necessary for actual combustion; Determining whether the rotational speed of the blowing fan represents the rotational speed by the amount of heat required for actual combustion; Determining whether the blower fan current detected by the blower fan current detector is smaller than the upper limit and larger than the lower limit if the rotation speed of the blower fan is equal to the required heat; As a result of the above determination, if the current flowing in the blower fan is smaller than the upper limit and larger than the lower limit, the flow returns to the initial stage, and if the current flowing in the blower fan is not greater than the upper limit or less than the lower limit, safe stopping the boiler. Blow fan speed correction method for safe combustion of the boiler. The method according to claim 8, If it is determined whether the number of revolutions of the blower fan indicates the number of revolutions required for the actual combustion, and if the number of revolutions of the blower fan does not equal the required amount of heat, the step of determining whether a predetermined time (l) has elapsed is further performed. ) Is not passed, the fan returns to the step of outputting the current required to rotate at the rotational speed required for the actual combustion, and if the predetermined time (l) has elapsed, the boiler is safely burned. Blow fan speed correction method for the. The method according to claim 8, The upper and lower limit determination criteria for the current value of the blowing fan during combustion is 5-10% of the calorie reference value, the blowing fan rotation speed correction method for the safe combustion of the boiler.

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