KR100607854B1 - Condensing boiler system and control method for operating thereof - Google Patents

Abstract

Disclosed are a condensing boiler system having a structure in which water is always supplied to a tube in a condensation heat exchanger to maximize the thermal efficiency by maximally recovering sensible heat and latent heat of exhaust gas. A control method of a condensing boiler system for supplying water to a boiler body through a condensation heat exchanger includes: detecting a level of water level filled in the boiler body; An initial water supply process of maximizing the amount of water supplied to the condensation heat exchanger until the detected water level is a predetermined normal water level; When the water level detection information is a level value above the normal level, the water supply to the condensation heat exchanger is increased or decelerated so that the detected level value follows the preset value so that the water always flows to the condensation heat exchanger according to the steam discharge amount. Control method of the condensing boiler system, characterized in that consisting of a water supply control process.

Condensing boiler, inverter, feed water pump, level sensor, induction motor,

Description

CONDENSING BOILER SYSTEM AND CONTROL METHOD FOR OPERATING THEREOF}

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

FIG. 2 is a view showing a schematic diagram of a passion mountain of the condensing boiler system shown in FIG. 1. FIG.

3 is a diagram showing the configuration of the water level sensor shown in FIGS.

4 is a data value of driving signal information stored in the memory shown in FIGS. 1 and 2, which describes a table value for generating a linearly corresponding driving control signal from a normal level to a high level. For drawing.

5 is a view showing a water supply control flow of the boiler drum according to a preferred embodiment of the present invention.

6 is a graph showing the operating state of the feed pump according to the control of FIG.

<< explanation of the code about part of drawing >>

5: combustion chamber, 10: boiler body,

12 burner 14 blower,

15: water drum, 16: air preheater,

18: condensation heat exchanger, 20: level sensor,

25: analog to digital converter, 30: control unit,

40: inverter, 50: feed water pump,

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a condensing boiler system, in particular water is always supplied to the tubes in the condensation heat exchanger to maximize the sensible heat and the condensing latent heat of the waste gas. The present invention relates to a condensing boiler system having a structure for maximizing thermal efficiency by recovering the same, and a control method thereof.

In general, the condensing boiler has a structure to maximize the thermal efficiency by absorbing the sensible and latent heat of exhaust gas as useful heat. Such condensing boilers have been further developed in boilers using Liquefied Natural Gas (LNG) as fuel.

The structure of the condensing boiler having the above characteristics is made of a heat pipe type air pre-heater and a spiral tube in an exhaust gas passage through which waste gas is discharged. A condensing economizer is installed in series to recover the sensible heat and the latent heat of condensation to maximize thermal efficiency.

The air preheater of the condensing boiler absorbs the heat of the exhaust gas by lowering its temperature by preheating the combustion air supplied to the burner as the heat of the high temperature exhaust gas discharged from the boiler body, as is well known in the art. It is to be discharged. At this time, the exhaust gas includes a high temperature steam that absorbs about 10% of the heat of vaporization (latent heat) from the heat of combustion (high unit calorific value) generated during burner combustion. In addition, the speed increase heat exchanger is connected in series to the outlet of the air preheater, and the spiral tube therein is supplied with low temperature water supplied from the outside.

When the high temperature exhaust gas discharged from the air preheater flows low temperature water into the spiral tube while it is in contact with the surface of the spiral pipe installed inside the condensation heat exchanger, the temperature of the heat transfer surface of the spiral tube is lower than the dew point. The temperature of the water flowing inside the spiral tube is increased by the latent heat of condensation of water vapor contained in the exhaust gas. By this condensation process, pollutants such as carbon dioxide (CO ₂ ) and nitrogen oxides (NOx) contained in the exhaust gas are dissolved in the condensate generated on the surface of the spiral tube and discharged.

At this time, since the outlet of the spiral tube is connected to the drum of the hot water tank or the boiler body, the sensible heat and the latent heat of condensation are recovered as hot water. Therefore, condensing boiler recovers sensible and latent heat of exhaust gas into combustion air and hot water to reduce environmental pollutant emission, reduce fuel, increase operating efficiency, improve steam dryness from boiler body, and change pressure of boiler body water drum. There are many effects, such as less.

Maintaining a constant water level by supplying water into the boiler body through the condensation heat exchanger as described above can be used for combustion management, for example, to reduce the efficiency of sensible heat and latent heat recovery of condensate, to discharge pollutants, to reduce fuel consumption, It is very important to manage the reduction of operation noise and power consumption.

In other words, if the water level in the boiler body is not properly maintained, the recovery efficiency of sensible heat and condensation heat of exhaust gas is lowered and hunting is caused by combustion, causing energy loss, and the pressure and temperature of steam are continuously changed. If the required level of pressure or temperature cannot be maintained properly, and the water supply is not well controlled, and the water level is too high, steam and water are released together to reduce the dryness of the steam.

Therefore, in order to maximize the efficiency by efficiently recovering the sensible and latent heat of exhaust gas from the condensing boiler and reducing the emission of pollutants, it is understood that cold water must always be supplied to the condensation heat exchanger.

The conventional technique of supplying water to the condensation heat exchanger is to fill the level of the boiler body, for example, the boiler water or the boiler drum, which is heated when the burner is burned by a level sensor which detects the level of the water level, such as a predetermined low level, normal level, and high level. By sensing step by step, the method of replenishing water through the condensation heat exchanger by driving the water supply pump in an "on" / "off" manner according to the detected water level has been mainly applied.

For example, if the water level sensor by the electrode or the water level sensor using the flute switch detects the water level of the boiler body at low level, the water supply pump is driven to supply water to the boiler body through the condensation heat exchanger. When the water level was detected as a high level, the intermittent water supply system was adopted to shut off the water supply by turning off the water supply pump.

The conventional intermittent water supply technology as described above operates the feed water pump when the water level in the boiler body is lower than the proper level according to the amount of steam evaporated and discharged by the boiler operation until the water level in the boiler body reaches a certain level. Although configured to automatically feed water, the water level in the boiler body could not always be kept constant.

That is, the technical configuration according to the conventional method drives the water supply pump at a low water level and blocks the driving of the water supply pump when the water level inside the boiler body becomes high by the water supply operation so that the water level fluctuation range is large and the quality of steam is good. I couldn't. In addition, by intermittently driving the feed water pump, water does not always flow through the spiral tube of the condensation heat exchanger, and the recovery efficiency of the sensible heat of the exhaust gas and the latent heat of condensation is low.

In addition, the condensing boiler is designed to operate at about 40% load because the use of steam varies depending on the season, it is common that the feed water pump is designed to 1.5 times the maximum capacity of the boiler. The feed water pump designed with this capacity operates around 15 minutes per hour on average, resulting in high steam dryness caused by fluctuations in boiler water level, water pressure change in the boiler body's water drum, and electricity consumption due to on / off feed water pump. Was low.

Accordingly, an object of the present invention is to provide a condensing boiler system and a control method thereof capable of recovering sensible heat and latent heat of condensation of exhaust gas to the maximum.

Another object of the present invention is to provide a condensing boiler system having a structure capable of recovering the sensible heat and the latent heat of condensation of exhaust gas at the same time, minimizing the emission of pollutants, and increasing the combustion efficiency, and a control method thereof. .

Still another object of the present invention is to digitally detect the water level of the boiler main body that changes according to the amount of change in the load (water evaporation amount), thereby continuously controlling the rotation speed of the feed water pump so that water is always supplied through the condensation heat exchanger. The present invention provides a condensing boiler system structure and a control method thereof that increase condensing efficiency and combustion efficiency.

Still another object of the present invention is to digitally detect the water level of the boiler body and adapt it to the linear speed of rotation of the feedwater pump consisting of induction motors so that heat exchange can always be achieved in the condensation heat exchanger. It is to provide a structure and a control method of the condensing boiler system with increased.

Condensing boiler system according to the present invention for achieving the above object comprises a combustion chamber having an exhaust gas discharge passage, a water drum formed around the combustion chamber filled with water and a burner installed in the combustion chamber to generate flames A boiler body; An air preheater installed on an exhaust gas discharge passage of the boiler body and preheating the temperature of combustion air supplied from the outside by sensible and latent heat of the exhaust gas; Installed in series with the air preheater having a tube for supplying water supplied from the outside to the water drum therein, and sensible heat of the exhaust gas by heating the water flowing into the tube by the high temperature exhaust gas discharged from the air preheater; A condensation heat exchanger for recovering the latent condensation heat; A blower which rotates in response to a drive signal and supplies combustion air preheated by the air preheater to the burner; A water level level detector for outputting digital data corresponding to the level filled in the water drum of the boiler body; A water supply pump installed between a water supply tank and a water supply port of a tube in the condensation heat exchanger, and rotated at a rotational speed adapted to a driving control signal to supply water in the water supply tank to the tube of the condensation heat exchanger; An inverter generating a drive control signal for driving the feed water pump at a rotational speed corresponding to a drive signal; A memory in which drive signal information for generating a linearly corresponding drive control signal from a water level of the water drum to a high water level is stored; The water supply pump is driven to the maximum until the water level detection information output as digital data from the water level level detector is a predetermined normal water level, and when the water level detection information is a level value above the normal water level, the detected level value is And a control unit for driving the feedwater pump to increase or decrease the water supply pump by providing a drive control signal to follow the preset target water level to the inverter.

Preferably, the control unit includes the memory in an internal nonvolatile memory area.

The water level sensor includes a capacitive sensor whose capacitance changes in response to a level filled in the water drum of the boiler body, and an analog to digital converter for converting and outputting the output of the capacitive sensor into digital data. ADC).

According to another aspect of the present invention, there is provided a method of controlling a condensing boiler system, the method including: sensing a level of water filled in the boiler body; An initial water supply process of maximizing the amount of water supplied to the condensation heat exchanger until the detected water level is a predetermined normal water level; And a water supply control process of increasing or decelerating a water supply to the condensation heat exchanger such that the detected level value follows a predetermined target water level level when the water level level detection information is a level value equal to or higher than a normal water level.

The water supply control process includes a deceleration process of decelerating the amount of water supplied to the condensation heat exchanger so that the information of the detected water level is followed by a target water level when the detected water level detection information is a value above a normal water level, and the detected water level. When the level detection information is less than or equal to the normal water level, it is characterized in that the increase in the water supply to the condensation heat exchanger so that the detected water level to follow the predetermined target water level.

Hereinafter, exemplary embodiments of the present invention will be described in detail with reference to the accompanying drawings. It should be understood, however, that the present invention may be embodied in many different forms and should not be construed as limited to the embodiments set forth. It should be noted that the embodiments of the present invention described below are intended to sufficiently convey the spirit of the present invention to those skilled in the art.

1 and 2 are views showing a block diagram of a condensing boiler system and a passion mountain thereof according to a preferred embodiment of the present invention, and FIG. 3 is a block diagram of the water level sensor shown in FIGS. 1 and 2. One drawing. 4 is a data value of driving signal information stored in the memory shown in FIGS. 1 and 2, which describes a table value for generating a linearly corresponding driving control signal from a normal level to a high level. It is a figure for following.

1 and 2, the condensing boiler body 10 according to a preferred embodiment of the present invention is a combustion chamber (5) having a waste gas (WG) discharge passage, for example, an association 11, the combustion chamber Water drum 15 formed around (5) and filled with water and burner 12 installed at the inlet of the combustion chamber 5 to generate flame. At this time, the water drum 15 of the boiler body 10 is connected to a water level level detector 20 for sensing the amount of water filled therein, and a water supply valve connected to a water supply tube WS. A discharge valve V2 connected to the V1 and the steam supply tube SS is connected to supply water into the water drum 15 or to discharge steam heated by the burner 12.

An air preheater 14 is installed on the outlet side of the pipe 11 in which exhaust gas of the boiler body 10 is discharged, and combustion air CA is supplied from the outside by sensible and latent heat of the exhaust gas. Preheat). The combustion air preheated by the air preheater 14 is supplied to the burner 12 by the rotation of the blower 16 provided in the lower part of the burner 12. At this time, it is well known that the blower 16 is composed of a flow-type electric motor, the rotational speed is controlled according to the load amount by the inverter (not shown) control.

The condensation heat exchanger (18) is installed in series with the air preheater (14) with a tube for supplying water supplied from the outside to the water drum (15), for example, a spiral tube (19). The water flowing to the tube 19 is heated by the hot exhaust gas discharged from the preheater 14 to recover the sensible heat and the latent heat of condensation of the exhaust gas. The condensate generated at this time is discharged to the neutralization treatment facility (60).

The feed water pump 50 is installed between the feed water tank (not shown) and the valve V1 connected to the feed port of the spiral tube 19 in the condensation heat exchanger 18, and rotates at a rotational speed adapted to the drive control signal. The water in the water supply tank is supplied to the water drum 15 through the tube 19 of the condensation heat exchanger 18. At this time, it is preferable that the feed water pump 50 uses an induction motor whose rotation speed is changed by frequency control.

The output of the level sensor 20 is input to the ADC 25, and the ADC 25 converts the input level sensor into digital data and provides it to the controller 30.

The controller 30 accesses the information of the drive signal corresponding to the output of the ADC 25 from the memory 35 and inputs it to the inverter 40, and the inverter 40 at a speed corresponding to the input drive signal. The feed pump 50 is driven. As shown in FIG. 4, the memory 35 stores information of a plurality of driving signals for controlling the rotational speed of the feed water pump 50 in response to the water level detection information output from the ADC 25. For example, information for controlling the rotational speed of the feed water pump 50 to 0% to 100% is stored.

Therefore, the controller 30 may accelerate and decelerate the water supply pump 50 from the rotational drive speed to the maximum speed at the maximum speed according to the output information of the ADC 25.

As shown in FIG. 3, the level sensor 20 shown in FIGS. 1 and 2 is a sensor that outputs an analog voltage or current corresponding to a change in capacitance value according to the level. The output of the sensor is input to the ADC 25 shown in Figs. 1 and 2, the ADC 25 converts the output of the water level sensor 20 to a digital data value and outputs it to the control unit 30. . *

In the embodiment of the present invention, for convenience of description, the resolution (resolution) of the ADC 25 employed in the embodiment of the present invention is assumed to be 8 bits. In addition, when the height of the water filled in the water drum 15 is lower than or equal to the normal level, the digital data output from the ADC 25 is negative, and when the normal level is zero, the output digital data is 0 (decimal), and the high level is high. It is assumed that the offset of the ADC 25 is preset so that the output digital value becomes 256 (decimal) when is. In addition, in the present invention, it is assumed that the target water level is set to any one of a value between the high water level and the normal water level.

By the above setting, it can be seen that the value of the ADC is 0 when the water level of the water drum 15 is lower than the normal level, and the value of the ADC 25 is outputted by 256 when the water level is high. There is information that drives the feed water pump 50 at 100% when the output value of the ADC 25 is 0, and when the output value of the ADC 25 is 256 to block the drive of the feed water pump 50 The information is matched. Therefore, the controller 30 can know that the rotational speed of the feed water pump 50 can be divided and accelerated and decelerated in multiple stages when the water level filled in the water drum 15 is between the normal water level and the target water level.

In the condensing boiler of the present invention configured as described above, the controller 30 controls the water supply pump 50 in 256 steps according to the output of the water level level detector 20 and the ADC 25 for detecting the water level in the water drum 15. By shifting and controlling the water level in the water drum 15 between the normal water level and the target water level, continuous water is supplied to the condensation heat exchanger 18, thereby further increasing the recovery rate of the sensible heat of the exhaust gas and the latent heat of condensation.

This operation will be more clearly understood by the following description.

5 is a view showing a water supply control flow of the boiler drum according to a preferred embodiment of the present invention, Figure 6 is a graph showing the operating state of the water supply pump according to the control of FIG.

1 to 6 will be described in more detail the operation control of the condensing boiler according to a preferred embodiment of the present invention and the recovery operation of the sensible heat of the exhaust gas and the latent heat of condensation according to the control.

When the boiler is operated, the level sensor 20 outputs a voltage corresponding to the capacitance that changes according to the level of water filled in the water drum 15 to the ADC 25. The ADC 25 converts an analog signal output from the level sensor 20 into a digital data value and inputs it to the controller 30.

At this time, the controller 30 reads the digital data value output from the ADC 25 in step 102 of FIG. 4 to determine whether the water level in the water drum 15 is a normal water level in step 104. If it is determined that the digital data value output from the ADC 25 of step 104 is equal to or less than "0", the controller 30 determines that the water level in the water drum 15 is lower than or equal to the normal water level in step 106. The water supply pump 50 outputs an initial water supply driving signal for driving at a rotational speed of 100% to the inverter 40.

The inverter 40 outputs an initial water supply drive control signal for rotating the feedwater pump 50 at a rotational speed of 100% in response to the initial water supply drive signal. At this time, the water supply pump 50 is driven by 100% of the water filled in the external water supply tank to pump the water drum 15 of the boiler body 10 by supplying to the water inlet of the spiral tube 19 in the condensation heat exchanger (18). ) Is filled with water.

When the height of the water supplied to the water drum 15 by the above process is at the normal water level level, the control unit 30 at the water level level of the water drum 15 is normal by the processes 102 and 104 of FIG. The water level is detected. This normal water level makes the steam dry well during boiler operation.

The burner 12 of the boiler body 10 in which water is supplied to the water drum 15 at the normal water level by the above process is supplied to the combustion air supplied through the air preheater 14 by the operation of the blower 16. CA and the fuel (for example, liquefied natural gas) supplied from the outside are mixed and combusted in the combustion chamber 5 so that the water in the water drum 15 is heated, and steam is discharged through the steam discharge pipe SS. The temperature of the exhaust gas generated in the combustion chamber 5 is about 260 degrees and is discharged to the air preheater 14 through the exhaust gas discharge passage consisting of the pipe 11. The air preheater 14 supplies the combustion air, which is supplied to the room temperature by the blower 16 to the burner 12, with the combustion air preheated to about 120 degrees by the high temperature exhaust gas.

Exhaust gas having a temperature of about 160 degrees from the air preheater 14 is supplied to the spiral tube 19 in the condensation heat exchanger 18 supplied by the operation of the feed water pump 50. At this time, the water flowing in the spiral tube 19 is heated to about 30 degrees or more to recover the sensible heat and the latent heat of condensation of the exhaust gas, and the condensed water is discharged to the neutralization treatment facility to remove carbon dioxide (CO ₂ ) and nitrogen contained in the exhaust gas. Emissions of pollutants such as oxides (NOx) are reduced.

On the other hand, after the initial water supply process, the controller 30 determines that the water level in the water drum 15 is above the normal water level in step 104 of FIG. 4, and information of the driving signal corresponding to the detected water level level in step 108. Is accessed from the memory 25 and input to the inverter 40.

For example, if the detected water level of the water drum 15 is lower than the level of the target water level, the controller 30 accesses the corresponding drive signal from the memory 35 that stores the information of the drive signal as shown in FIG. 4. By increasing the rotational speed of the water supply pump 50 to increase the water supply, on the contrary, if the water level is higher than the target water level, the rotational speed of the water supply pump 50 is reduced to reduce the water supply. At this time, the control of the rotational speed of the feed water pump 50 depends on the resolution (resolution) of the ADC 25, but in the embodiment of the present invention, the speed can be adjusted in 256 steps.

Accordingly, by the water supply control as described above, the rotational speed of the water supply pump 50 is reduced or increased according to the detected water level so that the water level in the water drum 15 follows the target water level as shown in FIG. The fluctuation range of the water level can be stabilized to improve the dryness (quality) of the steam, and water can always be flowed into the condensation heat exchanger 18 to increase the recovery rate of sensible heat and latent heat contained in the exhaust gas. The thermal efficiency can be further increased.

As described above, the condensing boiler according to the present invention executes the initial water supply by driving the water supply pump to the maximum until the level of the water filled in the water drum is at the normal level, and proportionally increases / decreases the water supply pump according to the level change from the normal level. By continuously supplying water to the condensation heat exchanger by proportional deceleration control operation, the recovery rate of the sensible heat of the exhaust gas and the latent heat of condensation can be increased, and the emission of environmental pollutants contained in the exhaust gas can be reduced. In addition, it is possible to minimize the pressure change in the boiler body water drum can improve the dryness of the steam.

Claims (5)

A condensing boiler system includes: a boiler body including a combustion chamber having an exhaust gas discharge passage, a water drum formed around the combustion chamber and filled with water, and a burner installed in the combustion chamber to generate a flame; A condensation heat exchanger having a tube for supplying water supplied from the outside to the water drum and heating the water flowing into the tube by the high temperature exhaust gas to recover sensible heat and latent heat of condensation of the exhaust gas; A water level level detector for outputting digital data corresponding to the level filled in the water drum of the boiler body; A water supply pump installed between a water supply tank and a water supply port of a tube in the condensation heat exchanger, and rotated at a rotational speed adapted to a driving control signal to supply water in the water supply tank to the tube of the condensation heat exchanger; An inverter generating a drive control signal for driving the feed water pump at a rotational speed corresponding to a drive signal; A memory for storing driving signal information for generating a linearly corresponding driving control signal from the water level of the water drum to a target water level; The water supply pump is driven to the maximum until the water level detection information output as digital data from the water level level detector is at a normal water level, and when the water level detection information is at a level value above the normal water level, the detected level value is preset. Condensing boiler system comprising a control unit for providing a drive control signal to follow the value of the set water level level to the inverter to increase or decrease the feed water pump. The air preheater of claim 1, further comprising: an air preheater installed on an exhaust gas discharge passage of the boiler main body and preheating the temperature of combustion air supplied from the outside by the high temperature exhaust gas and then discharging the air to the condensation heat exchanger; And a blower which is rotated according to a drive signal and supplies the combustion air preheated by the air preheater to the burner. The liquid level sensor according to claim 1 or 2, wherein the water level sensor detects a capacitance change in response to a level filled in a water drum of a boiler body, and converts and outputs the output of the full capacitance sensor into digital data. Condensing boiler system, characterized by consisting of analog to digital converters. In the control method of the condensing boiler system for supplying water to the boiler body through a condensation heat exchanger, Detecting a level of water filled in the boiler body; An initial water supply process of maximizing the amount of water supplied to the condensation heat exchanger until the detected water level is a predetermined normal water level; And a water supply control process of increasing or decelerating the water supply to the condensation heat exchanger so that the detected level value follows the predetermined target water level level when the water level detection information is a level value equal to or higher than a normal water level. Control method of condensing boiler system. The dewatering process of claim 4, wherein the water supply control process decelerates the amount of water supplied to the condensation heat exchanger so that the information of the detected water level is followed by a target water level when the detected water level detection information is equal to or greater than a normal water level. And increasing the amount of water supplied to the condensation heat exchanger such that the detected water level is followed by a predetermined target water level when the detected water level detection information is a value below a predetermined target water level. The control method of the condensing boiler system.

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