KR20220093865A - Method of detecting a blocking of air supplying and exhausting pipes of combustion facilities - Google Patents

Abstract

The present invention relates to a method for detecting the blocking of an air supplying and exhausting pipe of a combustion device. When a combustion request occurs, a fan is operated at a predetermined purge rotating rate before combustion, and the supply pressure of gas supplied into a mixing chamber via a gas supply valve is detected on the gas discharge line of the gas supply valve to make mixed gas, which burns in a combustor. Normal combustion is performed or whether the air supplying and discharging pipe of a combustion device has been blocked is detected depending on the result of comparing the detected pressure with predetermined purge pressure or predetermined combustion pressure. If the blocking of the air supplying and discharging pipe is confirmed, the fan is stopped to stop the combustion operation of the combustor and the fan of the error-generating combustion device is stopped to stop the combustion operation and to issue an error. According to the present invention, if the supply pressure of gas supplied into the mixing chamber is detected on the gas discharge line of the gas supply valve, no gas detection or mixed gas detection error occurs, thereby preventing claims for products. The disadvantage of using an expensive differential pressure sensor as an additional component to measure high differential pressure in order to detect the entire range from the maximum amount of heat to the minimum amount of heat during combustion in an existing method of detecting the pressure of supplied air can be solved. Unsafe combustion that can cause dangers such as overheating accidents can be prevented and product safety can be improved by detecting whether the air supplying and exhausting pipe of the combustion device has been blocked by using a pressure sensor cheaper than a high-priced differential pressure sensor.

Description

Method of detecting a blocking of air supplying and exhausting pipes of combustion facilities

The present invention relates to a combustion device such as a boiler or a water heater, and more particularly, to a method for detecting supply/exhaust closure of a gas supply pressure combustion device.

Combustion devices that operate heating or hot water by burning fuel such as gas or oil, such as boilers or water heaters, are installed in a place (eg, a room or living room) where the combustion controller installed in the combustion device is separated from the combustion device body. A combustor (eg, a combustor including a burner and a heat exchanger, etc.) in response to a request for control of a combustion operation (eg, heating operation or hot water operation) of a user who operates a thermostat (also called a room controller) and outputting a temperature control signal works by burning

The above-described combustion devices (eg, boilers or water heaters) cannot burn normally when the supply pipe or exhaust pipe is closed. When the actual supply and exhaust closure was confirmed by detecting the supply and exhaust closure, the combustor was stopped.

On the other hand, in the related art, in order to detect the supply/exhaust closure of the combustion device, a method of detecting the pressure of air supplied into the mixing chamber to make a mixed gas that is burned in the combustor, and a fan supplying air supplied to the interior of the mixing chamber A method of detecting a change in the motor capability of

However, the method of detecting the pressure of supplied air as described above has a disadvantage in that an expensive differential pressure sensor must be used as an additional component to measure the differential pressure high in order to detect the entire range from the maximum amount of heat to the minimum amount of heat during combustion. .

In contrast, in the method of detecting the change in the motor current of the fan as described above, quality control of the current according to the motor capability of the fan must be maintained, and a lot of effort is required for quality control.

10-2013-0042773 A

The present invention is to solve the conventional problems as described above, and an object of the present invention is to create a mixed gas that is combusted in a combustor after operating a fan at a predetermined purge rotation speed before combustion when a combustion request occurs For this purpose, the supply pressure of the gas supplied into the mixing chamber via the gas supply valve is detected on the gas discharge line of the gas supply valve, and the detected pressure is compared with a predetermined purge pressure or a predetermined combustion pressure. When the actual supply and exhaust closure is confirmed by detecting whether the supply and exhaust of the combustion device is closed or not, the fan is stopped to stop the combustion operation of the combustor. It is to provide a method for detecting closure of supply and exhaust of combustion equipment.

In order to achieve the object of the present invention as described above, in the combustion device supply/exhaust closure detection method according to the present invention, when a combustion request occurs, the fan operates at a predetermined purge rotation speed before combustion and then burns in the combustor a first process of detecting the supply pressure of the gas supplied into the mixing chamber via the gas supply valve to make a mixed gas of ; a second process of detecting a supply pressure of gas on a gas discharge line of the gas supply valve after normal combustion if the detected pressure is normal in the first process, and comparing the detected pressure with a predetermined combustion pressure; And if the detected pressure in the second process is abnormal, extinguish the fire and operate the fan at a predetermined purge rotation speed, detect the supply pressure of gas on the gas discharge line of the gas supply valve, and set the detected pressure in advance When the detected pressure is abnormal as a result of comparison with the determined purge pressure, a third process of determining that the combustion device is closed for supply air or exhaust gas, stops the fan, stops the combustion operation of the combustor, and generates an error; characterized in that it consists of.

In the combustion device supply/exhaust closure detection method according to the present invention, the detection pressure is the following formula, purge pressure × A < detection pressure < purge pressure × B < where A and B are pre-purge according to the product performance of the combustion device (Pre-purge) or post-purge (Post-purge) If the magnification for setting the safe range with respect to the reference pressure in the state is satisfied, it is characterized in that it is determined as normal.

In the combustion device supply/exhaust closure detection method according to the present invention, the detection pressure is the following formula, combustion pressure × C < detection pressure < combustion pressure × D (where C and D are normal combustion according to the product performance of the combustion device) It is characterized in that if it satisfies the magnification for determining the safe range with respect to the reference pressure in the state, it is determined as normal.

In the method for detecting air supply/exhaust closure of a combustion device according to the present invention, in the second process, after a combustion stabilization time has elapsed after normal combustion, the gas supply pressure is detected on the gas discharge line of the gas supply valve, and the detected pressure It is characterized in that it is compared with the combustion pressure for a predetermined closing detection time (eg, closing detection time 1).

In the method for detecting air supply/exhaust closure of a combustion device according to the present invention, in the third process, the detected pressure is compared with the purge pressure during a predetermined closure detection time (eg, closure detection time 2) for the detection pressure.

In the combustion device supply/exhaust closure detection method according to the present invention, if the detection pressure is normal during the closure detection time (eg, closure detection time 2) in the third process, another predetermined closure detection time (eg, closure detection time 3) During the return to the first process, it characterized in that it further comprises a fourth process of comparing the detected pressure and the purge pressure.

In the method for detecting air supply/exhaust closure of a combustion device according to the present invention, if the pressure detected in the first process is abnormal, during a predetermined closure detection time (eg, closure detection time 4) to confirm the supply air closure or exhaust closure of the combustion device Returning to the first process, it characterized in that it further comprises a fifth process of comparing the detected pressure and the purge pressure.

In the combustion device supply/exhaust closure detection method according to the present invention, in the fifth process, the normal detection pressure is not detected during the closure detection time (eg, closure detection time 4) and the closure detection time (eg, closure detection time 4) After this, it returns to the first process for another predetermined closure detection time (eg, closure detection time 3) and performs a fourth process of comparing the detected pressure and the purge pressure.

According to the present invention, when the supply pressure of the gas supplied into the mixing chamber is detected on the gas discharge line of the gas supply valve, there is no gas detection or mixed gas detection error, so claims against the product can be prevented, and In the pressure detection method, it can solve the disadvantage of using an expensive differential pressure sensor as an additional component to measure the differential pressure high in order to detect the entire range from the maximum amount of heat to the minimum amount of heat during combustion. It is possible to prevent unsafe combustion that can cause risks such as overheating accidents and improve product safety by detecting whether or not supply and exhaust of combustion devices are closed with a cheaper pressure sensor.

1 is a block diagram showing an embodiment of a combustion control device for a combustion device for performing a method for detecting shut-off of supply/exhaust closure of a combustion device according to the present invention.
Figure 2 is a flowchart illustrating a method for detecting a combustion device supply/exhaust closure according to the present invention.
Figure 3 is an embodiment showing a boiler to which the combustion device supply and exhaust closure detection method according to the present invention is applied.
4 is a graph showing the relationship between the fan rotation speed and the amount of heat of a combustion device according to the present invention.
5 is a graph showing the relationship between the fan rotation speed and the supply pressure of gas supplied into the mixing chamber according to the present invention.
6 is a graph showing a change in the supply pressure of the gas shown in FIG. 4 when supply/exhaust closure occurs in the purge state of the combustion device according to the present invention.
7 is a graph showing a change in the supply pressure of the gas shown in FIG. 4 when the combustion device supply/exhaust closure occurs according to the present invention.

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

The combustion device supply/exhaust closure detection method according to the present invention described below is not limited to the following examples, and anyone with ordinary knowledge in the relevant technical field without departing from the gist of the technology claimed in the claims It has the technical spirit to the extent that it can be implemented with any changes.

Referring to FIG. 1 , the method for detecting air supply/exhaust closure of a combustion device according to the present invention is performed by the combustion control device 100 of a combustion device (eg, a boiler or a water heater).

The combustion control device 100 shown in FIG. 1 includes a fan 110 , a gas supply valve 120 , a mixing chamber 130 , a gas pressure sensor 140 , a combustor 150 , and a controller 160 . .

The fan 110 operates at a predetermined purge rotation speed before or after combustion, and supplies air to make a mixed gas to be combusted in the combustor 150 during combustion through an air supply pipe and the mixed gas into the combustor It is supplied to 150, and exhaust gas is discharged to the outside through an exhaust pipe before, after, or during combustion.

The gas supply valve 120 supplies gas to the inside of the mixing chamber 130 to make the mixed gas combusted in the combustor 150 .

The mixing chamber 130 makes 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 gas pressure sensor 140 detects the supply pressure of the gas supplied into the mixing chamber 130 via the gas supply valve 120 and transmits it to the controller 160 .

The gas pressure sensor 140 is preferably installed on the gas discharge line of the gas supply valve 120 to detect the gas supply pressure before reaching the inside of the mixing chamber 130 .

The combustor 150 operates by burning to maintain the hot water temperature at a user-set temperature required through a temperature controller of a combustion device (eg, a boiler or a water heater).

The combustor 150 preferably includes a burner and a heat exchanger inside the housing.

The controller 160 controls the combustion operation of the combustor 150, and controls the combustion operation of the combustor 150 according to the user set temperature during normal combustion after a combustion request is generated.

The controller 160 operates the fan 110 at a predetermined purge rotation speed before combustion after the combustion request is generated and then passes through the gas supply valve 120 to create a mixed gas that is combusted in the combustor 150. The supply pressure of the gas supplied into the mixing chamber 130 is detected on the gas discharge line of the gas supply valve 120 .

The controller 160 performs normal combustion according to a result of comparing the detected pressure with a predetermined purge pressure or a predetermined combustion pressure, or detects whether the supply/exhaust closure of the combustion device is closed. to stop the combustion operation of the combustor 150 and generate an error.

By the controller 160 of the combustion control device 100 of the combustion device according to the present invention configured as described above, the combustion device supply/exhaust closure detection method S100 according to the present invention is performed as shown in FIG. 2 .

3 is an embodiment showing a boiler to which the combustion device supply and exhaust closure detection method (S100) according to the present invention is applied, and illustrates the supply gas flow, supply air flow, mixed gas flow and exhaust gas flow in the boiler with arrows, have.

The combustion device to which the combustion device supply/exhaust closure detection method S100 according to the present invention is applied, such as the boiler or water heater shown in FIG. 3, shows the relationship between the fan rotation speed and the amount of heat of the combustion device as shown in FIG. 4, and FIG. The relationship between the fan rotation speed and the supply pressure (gas-air pressure) of the gas supplied into the mixing chamber 130 is shown as shown in FIG.

For reference, FIG. 4 shows that, during normal combustion of the combustion device, the amount of heat (gas amount) is displayed in the form of a straight line that increases proportionally to the minimum heat amount and the maximum heat amount in the maximum rotation speed and minimum rotation speed region of the fan 110 .

For reference, FIG. 5 shows the gas supply pressure detected before reaching the inside of the mixing chamber 130 by the gas pressure sensor 140 on the gas discharge line of the gas supply valve 120 during normal combustion of the combustion device. That is, the detected pressure is displayed in a straight line in which the detected pressure is proportionally decreased from the maximum rotation speed and the minimum rotation speed region of the fan 110 to the maximum rotation speed detection pressure and the minimum rotation speed detection pressure. It indicates that the purge rotation speed detection pressure corresponding to the purge rotation speed is displayed as less than the maximum rotation speed detection pressure.

When a combustion request occurs for a combustion device to which the combustion device supply/exhaust closure detection method S100 according to the present invention is applied, such as a boiler or water heater shown in FIG. 3 , the controller 160 purges the fan prior to combustion. ) The supply pressure of the gas supplied into the mixing chamber 130 via the gas supply valve 120 to make a mixed gas that is burned in the combustor 150 after operating at the rotation speed of the gas supply valve 120 . A first process (S110) of detecting the gas discharge line and comparing the detected pressure with a predetermined purge pressure is performed.

In performing the first process (S110), the controller 160 determines that the detected pressure received from the gas pressure sensor 140 is calculated by the following formula, for example, purge pressure×A<detected pressure<purge pressure×B<where , A and B are judged to be normal if they satisfy > the magnification for setting the safe range for the reference pressure in the pre-purge state or the post-purge state according to the product performance of the combustion device.

If the pressure detected in the first process (S110) is normal, the controller 160 operates the combustor 150 to perform normal combustion, and then the gas supply pressure on the gas discharge line of the gas supply valve 120 . , and a second process (S120) of comparing the detected pressure with a predetermined combustion pressure is performed.

In performing the second process (S110), the controller 160 determines that the detected pressure received from the gas pressure sensor 140 is calculated by the following formula, for example, combustion pressure×C<detected pressure<combustion pressure×D (herein, , C and D are judged as normal if they satisfy the magnification for determining the safe range for the reference pressure in the normal combustion state according to the product performance of the combustion device.

In addition, in performing the second process (S120), the controller 160 operates the combustor 150 to perform normal combustion, and after a combustion stabilization time elapses, on the gas discharge line of the gas supply valve 120 . The gas supply pressure is detected, and the detected pressure is compared with the combustion pressure for a predetermined closing detection time (eg, closing detection time 1).

If the detected pressure is abnormal in the second process (S120), the controller 160 stops the combustor 150 to extinguish the fire, operates the fan 110 at a predetermined purge rotation speed, and then If the detected pressure is abnormal as a result of detecting the supply pressure of gas on the gas discharge line of the gas supply valve 120 and comparing the detected pressure with a predetermined purge pressure, it is determined that the combustion device is closed to supply air or exhaust is closed, and the fan 110 ) to stop the combustion operation of the combustor 150 and perform a third process (S130) of generating an error.

In performing the third process (S130), the controller 160 determines that the detected pressure is determined by the following formula, for example, purge pressure×A<detected pressure<purge pressure×B<where A and B are products of the combustion device. If it satisfies the magnification for setting the safe range for the reference pressure in the pre-purge state or the post-purge state according to the performance, it is judged as normal.

In addition, in performing the third process ( S130 ), the controller 160 compares the detected pressure with the purge pressure during the predetermined closing detection time (eg, the closing detection time 2 ).

If, in performing the third process (S130), the detection pressure is normal during the closure detection time (eg, closure detection time 2), the controller 160 controls another predetermined closure detection time (eg, closure). During the detection time 3), the process returns to the first process (S110) and a fourth process (S140) of comparing the detected pressure and the purge pressure is further performed.

On the other hand, if the detected pressure in the first process (S110) is abnormal, the controller 160 determines a predetermined closure detection time (eg, closure detection time 4) to confirm the supply air closure or exhaust exhaust closure of the combustion device. While returning to the first process (S110), a fifth process (S150) of comparing the detected pressure and the purge pressure is performed.

If, in performing the fifth process (S150), the normal detection pressure is not detected by the gas pressure sensor 140 during the closure detection time (eg, closure detection time 4), and the closure detection time (eg, closure detection time) , when the closure detection time 4) has passed, the controller 160 returns to the first process S110 for another predetermined closure detection time (eg, closure detection time 3) to a fourth process of comparing the detected pressure and the purge pressure ( S140) is performed.

For reference, FIG. 6 is a graph showing a change in supply pressure of the gas shown in FIG. 4 when supply/exhaust closure occurs in the purge state of the combustion device according to the present invention, and the number of purge rotations corresponding to the number of purge rotations of the fan 110 is detected. It illustrates that the pressure appears lower than normal when the supply air is closed and higher than normal when the exhaust is closed.

For reference, FIG. 7 is a graph showing the change in the supply pressure of the gas shown in FIG. 4 when the supply/exhaust closure of the combustion device according to the present invention occurs, and the gas pressure sensor 140 on the gas discharge line of the gas supply valve 120 . The gas supply pressure detected before reaching the inside of the mixing chamber 130 by Compared with the normal detection pressure (see FIG. 5 ) displayed in a decreasing straight line, it is exemplified that it appears lower than normal when supply air is closed, and appears higher than normal when exhaust is closed.

As can be seen from the above, according to the present invention, when the supply pressure of the gas supplied into the mixing chamber 130 is detected on the gas discharge line of the gas supply valve 120, there is no gas detection or mixed gas detection error. An expensive differential pressure sensor must be used as an additional part to measure the differential pressure high in order to prevent claims against It is a pressure sensor that is relatively cheaper than an expensive differential pressure sensor, and detects whether the supply and exhaust of the combustion device is closed to prevent unsafe combustion that can cause risks such as overheating accidents and improve product safety. can

100: combustion control device 110: fan
120: gas supply valve 130: mixing chamber
140: gas pressure sensor 150: combustor
160: controller

Claims (8)

When a combustion request occurs, the fan 110 is operated at a predetermined purge rotation speed before combustion, and then the mixing chamber 130 via the gas supply valve 120 to make the mixed gas that is burned in the combustor 150. a first process (S110) of detecting the supply pressure of the gas supplied to the inside on the gas discharge line of the gas supply valve 120 and comparing the detected pressure with a predetermined purge pressure;
If the detected pressure is normal in the first process (S110), after normal combustion, the gas supply pressure is detected on the gas discharge line of the gas supply valve 120, and the detected pressure is compared with a predetermined combustion pressure. Step 2 (S120); and
In the second process (S120), if the detected pressure is abnormal, extinguish the fire and operate the fan 110 at a predetermined number of purge rotations. Then, the gas supply pressure on the gas discharge line of the gas supply valve 120 is If the detected pressure is abnormal as a result of comparing the detected pressure with the predetermined purge pressure, it is determined that the combustion device is closed to supply air or exhaust is closed, and the fan 110 is stopped to stop the combustion operation of the combustor 150 and correct the error. a third process that occurs (S130);
Combustion device supply and exhaust closure detection method, characterized in that consisting of. The method according to claim 1, wherein the detection pressure is
Purge pressure×A< Detection pressure < Purge pressure×B
If <A and B are the magnifications for setting the safe range for the reference pressure in the pre-purge state or post-purge state according to the product performance of the combustion device>, it is determined as normal Combustion device supply and exhaust closure detection method, characterized in that. The method according to claim 1, wherein the detection pressure is
Combustion pressure×C< Detection pressure < Combustion pressure×D
(Here, C and D are magnifications to determine the safe range for the reference pressure in the normal combustion state according to the product performance of the combustion device)
Combustion device supply/exhaust closure detection method, characterized in that it is determined as normal if it satisfies. The method according to claim 1, wherein in the second process (S120), the gas supply pressure is detected on the gas discharge line of the gas supply valve 120 after the combustion stabilization time has elapsed after the normal combustion is performed, and the detected pressure is set in advance. Combustion device supply/exhaust closure detection method, characterized in that it is compared with combustion pressure during the specified closure detection time. The method according to claim 1, wherein in the third process (S130), the detection pressure is compared with the purge pressure for a predetermined closing detection time. According to claim 5, wherein in the third process (S130), if the detected pressure during the closing detection time is normal, the fourth process (S110) of returning to the first process (S110) for another predetermined closing detection time and comparing the detected pressure and the purge pressure ( S140) Combustion device supply and exhaust closure detection method, characterized in that it further comprises. According to claim 1, wherein if the detected pressure in the first process (S110) is abnormal, return to the first process (S110) for a predetermined closure detection time in order to check the supply air closure or exhaust closure of the combustion device, the detected pressure and the purge pressure A combustion device supply and exhaust closure detection method, characterized in that it further comprises a fifth process (S150) of comparing. The method according to claim 7, wherein, in the fifth process (S150), when the normal detection pressure is not detected during the closing detection time and the corresponding closing detection time elapses, the process returns to the first process (S110) for another predetermined closing detection time, and the detection pressure and purging are performed. Combustion device supply and exhaust closure detection method, characterized in that performing a fourth process (S140) of comparing the pressure.

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