KR20090050452A - A combustion controlling method for a boiler - Google Patents

Abstract

A boiler combustion control method is disclosed. Adjusting the number of revolutions of the blower fan so that the ignition point is in the burner maximum operating range, and igniting the burner when the ignition point is in the burner maximum operating range; Increasing the number of revolutions and controlling the number of running of the burner in accordance with a preset heating preset temperature and sensed temperature. According to the boiler combustion control method according to the present invention, it is possible to reach the maximum heat within a short time by reducing the discharging time between the burners, can quickly meet the user's needs, thereby improving the customer's satisfaction of heating and hot water use Can be. In addition, by quickly raising and maintaining the room temperature to the set temperature of the room heating, unnecessary ignition operation process is omitted, it is possible to minimize the fuel consumption and increase the energy efficiency of the boiler.

Combustion, ignition point, burner, blowing fan, boiler, temperature

Description

A COMBUSTION CONTROLLING METHOD FOR A BOILER}

The present invention relates to a boiler combustion control method, and more particularly, to a method for controlling the combustion of the boiler by controlling the ignition of the burner group of the boiler.

Figure 4 is a block diagram showing the overall configuration of a conventional boiler.

Referring to FIG. 4, a boiler is a device used to supply hot water and heating water to a home or an office. Existing boiler 1 is an example of a gas boiler, a combustor 10 for burning gas for hot water supply, a water tank 20 for storing heating water, and different paths for circulation of hot and cold water. It has a secondary heat exchanger (30) having.

In the casing 11 of the combustor 10, a burner group 12 composed of a plurality of burners, a blower fan 13 for supplying combustion air, a primary heat exchanger 14, and the burner group 12 The ignition plug 15 for igniting), the frame rod 16 for detecting the ignition of the burner group, and the exhaust portion 18 for discharging the exhaust are formed on the upper surface of the combustor casing 11. In addition, a gas pipe 50 for supplying gas is provided below the burner group 12, and the gas pipe 50 has two electron valves 51 and 52 for passing gas at the time of energization, and to adjust the gas supply amount. Proportional valve 53 is installed.

The water tank 20 is provided in the water level detection sensor 21 for detecting the high and low water level of the heating water in the water tank, the overflow pipe 22 for discharging excess water, and the heating return pipe 24. A circulation pump 26 is installed in the water separator 23 and the water supply pipe 25 for supplying water to the primary heat exchanger 14 to circulate the heating water.

In addition, between the heating return pipe 24 and the direct water inlet pipe 34, the water supply valve 35 for replenishing the water when the water tank 20 is insufficient, clogging of the heating filter, blockage of the heating distributor. And a bypass pipe 38 for preventing the pressure from rising inside the gas boiler when the heating distribution pipe is blocked, and for circulating the flow of water by making an internal closed circuit of the gas boiler.

In addition, three sides 36 are installed in the water supply pipe 25 and the heating water supply pipe 37. The heating water heated by the first heat exchanger 14 by the three-sided valve 36 is circulated to the heating water supply pipe 37 through the water supply pipe 25, and the second heat exchanger through the water supply pipe 25. (30) and

Through the water separator 23 and the circulation pump 26 may be circulated to the first heat exchanger 14 through the water supply pipe 25 again.

In addition, the first heat exchanger 14 detects the temperature of the heating water discharged as the heating water having a specific temperature by the first heat exchanger 14 through the water supply pipe 25. And, a temperature sensor (TH2) for detecting the overheating temperature of the heating water flowing into the first heat exchanger 14 through the water supply pipe 25 is installed.

5 is a graph showing the relationship between the number of revolutions of the blowing fan and the calorific value shown in the temperature control in the conventional boiler.

Referring to FIG. 5, when the ignition operation of the existing boiler 1 is described, when power is supplied to the existing boiler 1, the current value of the proportional valve 53 is 0 in the existing boiler 1. In the blower fan 13 performs a prepurge to check whether the desired work. When the current value of the proportional valve reaches a predetermined current value, the existing boiler 1 ignites with a weak flame to prevent the explosion ignition of the burner group 12. The burner located on one side of the burner group 12 is ignited at the ignition point (a) by the spark plug 15 and the ignition operation is achieved while the flame of the ignited burner is guided to an adjacent burner.

This conventional boiler 1 performs the ignition operation in a multi-stage proportional control method for stable ignition and precise temperature control. That is, the existing boiler 1 performs ignition by gradually transferring the heat up to the maximum heat after ignition. If the burner group 12 is composed of a total of 14 burners, the existing boiler 1 ignites at the ignition point a as described above, and operates five burners at the AB LINE state, which is the minimum operation of the burners. . In addition, the existing boiler 1 reaches the C-D LINE state, which is the middle operation of the burner, through the B-C stage for the transfer, and operates nine burners in the C-D LINE state. Next, the existing boiler 1 reaches the E-F LINE state, which is the maximum operation of the burner, through the D-E stage for discharging, and operates 14 burners, that is, all the burners in the E-F LINE state.

Therefore, the conventional boiler 1 takes a proper time for stable discharging at each ignition stage, and thus has a problem in that it takes a predetermined time to go up to the maximum heat amount.

The technical problem to be achieved by the present invention is to provide a boiler combustion control method that can reach the maximum heat in a short time by reducing the discharging time between burners.

Another technical problem to be achieved by the present invention is to provide a boiler combustion control method for rapidly raising and maintaining a room temperature to a set room heating temperature.

In order to achieve the above technical problem, the boiler combustion control method according to the present invention comprises the steps of adjusting the number of revolutions of the blower fan so that the ignition point belongs to the complete region of burner maximum operation; And an ignition step of igniting a burner when the ignition point belongs to a complete area of burner maximum operation.

And in the ignition step, it is preferable to adjust the number of burners to be ignited according to the burner operating area.

Preferably the boiler combustion control method, further comprising the step of increasing the number of revolutions of the blowing fan to achieve perfection.

According to the boiler combustion control method according to the present invention, it is possible to reach the maximum heat within a short time by reducing the discharging time between the burners, can quickly meet the user's needs, thereby improving the customer's satisfaction of heating and hot water use Can be.

In addition, by quickly raising and maintaining the room temperature to the set temperature of the room heating, unnecessary ignition operation process is omitted, it is possible to minimize the fuel consumption and increase the energy efficiency of the boiler.

Hereinafter, with reference to the accompanying drawings will be described in detail a preferred embodiment of the boiler combustion control method according to the present invention.

1 is a block diagram schematically showing the configuration of a preferred embodiment of a boiler according to the present invention.

Referring to FIG. 1, a boiler according to the present invention includes a user interface unit 110, a temperature sensor 120, a display unit 130, a combustor driving unit 140, and a controller 150.

The user interface 110 is a conventional means for receiving various user manipulation commands such as heating set temperature and operation time setting, and may be implemented as a key button and a volume.

The temperature sensor 120 is a means for detecting a heating water temperature, and may be implemented as a thermistor.

The display unit 130 is a means for externally displaying a boiler set temperature and an operating state according to a user operation input, and may be implemented as an LED display device or a liquid crystal display device.

The combustor drive unit 140 is a burner group (reference numeral 12 of FIG. 4) installed in the boiler in accordance with the operation control signal input from the control unit 150, and a blowing fan (reference numeral 13 of FIG. 4) for supplying combustion air. And a primary heat exchanger (reference numeral 14 in FIG. 4), an ignition plug (reference numeral 15 in FIG. 4), etc. for igniting the burner group 12. That is, the combustor drive unit 140 performs a prepurge for checking whether the blower fan 13 operates, and drives the blower fan 13 according to the rotation speed calculated by the controller 150. The burners constituting the burner group 12 are ignited in accordance with the operation number calculated by 150.

2 is a graph showing the relationship between the rotational speed and the calorific value of the blowing fan in the temperature control in the boiler according to the present invention.

Referring to FIG. 2, the controller 150 controls the entire system. Preferably, the controller 150 may be implemented as a microprocessor including a ROM, a RAM, and a peripheral device.

The controller 150 calculates the number of revolutions of the blower fan 13 for which the ignition point a belongs to the quenching region 210 at the maximum operation of the burner, and the combustor drive unit 140 calculates the control unit 150. The blowing fan 13 is driven in accordance with the rotation speed c. That is, the controller 150 calculates the rotation speed of the blowing fan 13 for changing the ignition point from the ignition point a to the ignition point b. In addition, the control unit 150 checks whether the ignition point belongs to the burn-up area 210 of the burner maximum operation, so that the ignition point belongs to the burn-up area 210 of the burner maximum operation, and causes the combustor driver 140 to drive the spark plug. To control. Accordingly, the burners constituting the burner group 12 at the ignition point b are ignited. The burner operating area here means minimum burner operation, medium burner operation and maximum burner operation. In addition, the minimum burner operation, the middle burner operation and the maximum burner operation mean the number of predetermined burners operated and at the same time, the amount of combustion heat. That is, the number of burners to be ignited in each burner movable area varies according to the number of burners constituting the burner group 12, and thus the amount of combustion heat varies. For example, in the case where the total number of burners constituting the burner group 12 is fourteen, five, nine and fourteen burners are ignited at minimum burner operation, middle burner operation and maximum burner operation, respectively.

After the ignition is performed, the controller 150 calculates the rotation speed of the blower fan 13 to achieve perfection, and controls the blower fan 13 according to the rotation speed (b) calculated by the combustor drive unit 140. By controlling to drive, the ignition point b is changed to the point P. FIG. In this state, the number of revolutions of the blower fan 13 may be increased to a number of revolutions (a) to quickly operate the boiler 100 according to the present invention with the maximum calorific value.

In the conventional boiler 1, when the ignition is performed at a low burner at the maximum operation of the burner, the ignition zone 510 is included in the condensate generating zone 520, so that the ignition is performed at high calories. Depending on the external conditions such as explosion may occur or incomplete ignition. Accordingly, the existing boiler 1 performs the ignition operation in such a manner that the ignition is performed at the minimum operation of the burner and then transferred to the maximum operation of the burner after the extended combustion for a predetermined time to produce the maximum amount of heat. However, the boiler 100 according to the present invention immediately lowers the rotation speed (Hz) of the blower fan 13 at the ignition point (a) after prepurge, and then ignites in the burner full operation region 210 of the burner, and then blows the air. Out of the condensate generating region 220 by returning the rotation speed of the fan 13 to the combustion line ABCDEF, it is possible to reach the set temperature faster by having two ignition points (b, P) have. Therefore, the boiler 100 according to the present invention can shorten the discharging time between the burners to reach the maximum calories within a short time, and can quickly satisfy the needs of the user.

The controller 150 receives the heating water temperature detected by the temperature sensor 120, calculates a difference value by comparing the received heating water temperature with a preset heating set temperature, and operates the burner according to the calculated difference value. To determine the burner operating area.

The control unit 150 controls the appropriate number of burners to be ignited according to the determined burner operating area. In addition, the controller 150 selectively determines the ignition method according to the determined burner operating area. For example, when the burner operating area is determined to be the maximum burner operation, the controller 150 ignites all the burners or burner groups to be ignited at the maximum operation of the burner at the ignition point b. As another example, when the burner operating area is determined to be the minimum burner operation, the controller 150 corresponds to the burner minimum operation at the ignition point a without performing a procedure of bringing the ignition point a to the ignition point b. To burn as many burners or burner groups as possible.

According to this characteristic aspect, the boiler 100 according to the present invention can quickly rise and maintain the room temperature to the set temperature of the room heating, unnecessary ignition operation process can be omitted to minimize the fuel consumption and improve the energy efficiency of the boiler It can increase.

3 is a flowchart illustrating a process of performing a preferred embodiment of the boiler combustion control method according to the present invention.

Referring to FIG. 3, the combustor driving unit 140 performs a prepurge for checking whether the blower fan 13 operates in operation S300. Then, the control unit 150 calculates the rotation speed of the blowing fan for belonging to the ignition point in the burner maximum operation (S310). The combustor driver 140 reduces the number of revolutions of the blower fan by adjusting the rotation of the blower fan at the number of revolutions calculated by the controller 150 (S320).

The controller 150 checks whether the ignition point belongs to a complete area at burner maximum operation (S330). The combustor drive unit 140 drives the ignition plug to ignite the burner group 12 when the ignition point belongs to a complete area of burner maximum operation (S340). Herein, the controller 150 adjusts the number of burners or the burner group according to the burner operating area. For example, when the burner operating area is determined to be the maximum burner operation, the control unit 150 controls the burner to be ignited when the burner is fully operated. As another example, when the burner operating area is determined to be the minimum burner operation, the controller 150 controls the burner to be ignited at the maximum burner mode to be ignited.

After the ignition is performed, the controller 150 calculates the rotation speed of the blower fan 13 to achieve perfection (S350). The combustor drive unit 140 rotates the blowing fan 13 at the rotation speed of the blowing fan 13 calculated by the controller 150 (S360). The ignition point thus belongs to the complete area of the current burner operating area. At this time, the number of revolutions of the blower fan 13 may be increased up to the number of revolutions (a), thereby allowing the boiler 100 according to the present invention to be quickly operated with the maximum heat amount. According to this characteristic step, the boiler combustion control method according to the present invention can shorten the discharging time between the burners to reach the maximum heat amount in a short time, and can quickly satisfy the needs of the user.

The controller 150 receives the heating water temperature detected by the temperature sensor 120, and calculates a difference value by comparing the received heating water temperature with a preset heating preset temperature (S370). The controller 150 calculates the number of operation of the burner according to the calculated difference value (S380). In addition, the combustor driving unit 140 controls the rotation of the blower fan 13 and the supply of heat according to the operation number of the burner calculated by the controller 150 (S390). According to this characteristic step, the boiler combustion control method according to the present invention can quickly raise and maintain the room temperature to the set room heating temperature, and eliminate unnecessary ignition operation, thereby minimizing fuel consumption and improving the energy efficiency of the boiler. It can increase.

Although the preferred embodiments of the present invention have been shown and described above, the present invention is not limited to the specific preferred embodiments described above, and the present invention belongs to the present invention without departing from the gist of the present invention as claimed in the claims. Various modifications can be made by those skilled in the art, and such changes are within the scope of the claims.

1 is a block diagram schematically showing the configuration of a preferred embodiment of a boiler according to the invention,

2 is a graph showing the relationship between the rotational speed and the calorific value of the blower fan at the time of temperature control in the boiler according to the present invention;

3 is a flowchart illustrating a process of performing a preferred embodiment of the boiler combustion control method according to the present invention;

Figure 4 is a block diagram showing the overall configuration of a conventional boiler, and

5 is a graph showing the relationship between the number of revolutions of the blowing fan and the calorific value shown in the temperature control in the conventional boiler.

Claims (3)

Adjusting the number of revolutions of the blower fan so that the ignition point belongs to a complete area of burner maximum operation; And And an ignition step of igniting a burner when the ignition point belongs to a complete area of burner maximum operation. The method of claim 1, In the ignition step, Boiler combustion control method, characterized in that for controlling the number of burners to be ignited according to the burner operating area. The method according to claim 1 or 2, The boiler combustion control method, Increasing the number of revolutions of the blowing fan to achieve a perfection; boiler combustion control method further comprising.

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