KR102404468B1 - Exhaust gas analysis system for power plant - Google Patents

Abstract

The present invention discloses an exhaust gas analysis system for a power plant. The disclosed exhaust gas analysis system for a power generation plant is coupled to an exhaust duct of a power plant, and a sensing module for detecting and sucking ash of exhaust gas exhausted from the exhaust duct, and receiving an ash detection signal from the sensing module to detect the components of the ash The ash analysis unit to analyze, the sensor heating unit heating the sensing module to keep the ash detection temperature of the sensing module similar to the internal temperature of the exhaust duct and heating it above the set temperature value, and the exhaust gas of the exhaust duct is sent to the sensing module It is characterized in that it has an exhaust gas inducing part connected to the sensing module to be sucked in and supplying air to the sensing module. Therefore, the present invention can efficiently measure the ash component of the exhaust gas discharged to the exhaust duct of the power plant.

Description

Exhaust gas analysis system for power plant

The present invention relates to an exhaust gas analysis system for a power plant, and more particularly, to an exhaust gas analysis system for a power plant that can efficiently measure an ash component of an exhaust gas discharged to an exhaust duct of a power plant.

In general, power plants are largely classified into a nuclear power plant, a hydroelectric power plant, a thermal power plant, and a solar thermal power plant, and in recent years, a combined power plant is being built.

A double thermal power plant (Thermoelectric Power Plant) uses the heat of burning fuel such as coal, oil, and natural gas to produce high-temperature and high-pressure steam, and uses this high-temperature and high-pressure steam to rotate a steam turbine to produce electricity. .

On the other hand, the circulating fluidized bed combustion technology, which has been widely adopted in thermal power plants being built recently, blows air at an appropriate speed into a fluidized medium such as limestone and sand and coal particles made by pulverizing coal to an appropriate size. It is a method to make a fluidized bed (Suspended FluidIzed Bed) and supply it to the boiler for combustion.

Such circulating fluidized bed combustion has a very high heat transfer efficiency due to direct heat transfer by solid particles, and the combustion temperature in the furnace is much lower than the furnace temperature of the pulverized coal combustion method. In addition, because of its unique combustion characteristics, it circulates until the fluid is completely combusted, so unlike the pulverized coal combustion, low-quality coal with a low calorific value and a large amount of moisture can be burned, and combustion at a relatively low temperature (900℃ or less) is possible. Because it occurs, the generation of nitrogen oxides is significantly reduced. For this reason, there was also the advantage of not requiring a separate denitrification facility (SCR or SNCR) to comply with nitrogen oxide emission regulations.

Coal-fired boilers used in circulating fluidized bed combustion technology generate a large amount of dust such as fly ash, so a dust collector is installed at the rear end of the boiler, and an electric dust collector is mainly used as the dust collector.

The electrostatic precipitator largely includes a charging device, a rapper, and a dust discharge device, and the exhaust gas discharged from the boiler passes through the inside while the distribution is uniformed through the rectifier plate at the inlet side. And the ash contained in the exhaust gas is collected by the electrode plate including the discharge electrode and the dust collecting electrode, the dust collected by falling into the hopper by the churning device is processed.

In addition, various types of measuring devices for measuring ash included in exhaust gas are installed in the exhaust duct of the boiler or the electric dust collector.

However, the ash measuring apparatus of the boiler of the prior art as described above has a problem in that it is very difficult to analyze the ash component of the exhaust gas discharged along the duct.

Therefore, there is a need to improve it.

On the other hand, Republic of Korea Patent Registration No. 10-1817008 (registration date: January 03, 2018) discloses "a high-temperature tube corrosion measuring device in chlorine gas, a measuring method, and an analysis system using the measuring device".

The present invention was created by the above necessity, and it is possible to efficiently measure the ash component of the exhaust gas discharged to the exhaust duct of the power plant as well as effectively remove the ash attached to the sensing module to detect the ash. An object of the present invention is to provide an exhaust gas analysis system for a power plant that can improve

In order to achieve the above object, an exhaust gas analysis system for a power plant according to an aspect of the present invention includes: a sensing module coupled to an exhaust duct of a power plant, and sensing the ash of exhaust gas exhausted from the exhaust duct;

an ash analysis unit receiving the ash detection signal from the sensing module and analyzing the components of the ash;

a sensor heating unit which heats the sensing module to maintain the ash detection temperature of the sensing module similarly to the internal temperature of the exhaust duct and heats the sensing module above a set temperature value; and

an exhaust gas induction unit connected to the sensing module to supply air to the sensing module so that the exhaust gas of the exhaust duct is sucked into the sensing module;

The sensing module may include: a body coupled to an outer surface of the exhaust duct, in which an exhaust gas circulation passage for circulation of the exhaust gas and an ejection gas circulation passage for circulation of ejecting air of the exhaust gas induction unit are formed;

an ash detection probe coupled to the body so as to communicate with the exhaust gas circulation passage unit and detecting the ash contained in the exhaust gas;

an exhaust gas inlet nozzle part coupled to the body to communicate with the exhaust gas circulation passage part and transferring the exhaust gas from the exhaust duct to the ash detection probe; and

a gas discharge induction part coupled to the main body to communicate with the exhaust gas circulation passage part and the ejection gas circulation passage part, and guide the exhaust gas and the eject gas into the exhaust duct;

Exhaust gas analysis system for a power plant, characterized in that it comprises a.

As described above, the exhaust gas analysis system for a power plant according to an aspect of the present invention can continuously manage the sensing module for detecting the ash of the exhaust gas unlike the prior art, thereby improving the reliability of the sensing module, It has the effect of increasing the period of use.

In addition, the exhaust gas analysis system for a power plant according to the present invention has the effect of effectively removing the ash attached to the sensing module of the power plant to improve the detection performance of the ash detection probe.

1 is a block diagram for explaining an exhaust gas analysis system for a power plant according to an embodiment of the present invention.
2 is a perspective view illustrating a sensing module according to an embodiment of the present invention.
3 is a cross-sectional view for explaining a sensing module according to an embodiment of the present invention.
4 is a diagram illustrating an exhaust gas flow of a sensing module according to an embodiment of the present invention.

Hereinafter, a preferred embodiment of an exhaust gas analysis system for a power plant according to the present invention will be described with reference to the accompanying drawings. In this process, the thickness of the lines or the size of the components shown in the drawings may be exaggerated for clarity and convenience of explanation.

In addition, the terms to be described later are terms defined in consideration of functions in the present invention, which may vary according to the intention or custom of the user or operator. Therefore, definitions of these terms should be made based on the content throughout this specification.

1 is a block diagram for explaining an exhaust gas analysis system for a power plant according to an embodiment of the present invention, FIG. 2 is a perspective view for explaining a sensing module according to an embodiment of the present invention, and FIG. 3 is this view It is a cross-sectional view for explaining a sensing module according to an embodiment of the present invention, and FIG. 4 is a view showing an exhaust gas flow of the sensing module according to an embodiment of the present invention.

1 to 4 , the exhaust gas analysis system for a power plant according to an embodiment of the present invention includes a sensing module 110 coupled to an exhaust duct 10 of a power plant, and a sensing module 110 . The ash analyzer 120 for analyzing the component of the ash detected in the ash analysis unit 120, the sensor heating unit 130 for heating the sensing module 110, and the exhaust gas induction unit for inducing the inflow of exhaust gas to the sensing module 110 (140).

The sensing module 110 is coupled to the exhaust duct 10, and exhaust gas for ash analysis is circulated and discharged.

The ash analysis unit 120 receives the ash detection signal detected by the sensing module 110 from the sensing module 110 and analyzes the component of the ash. In addition, the ash analyzer 120 is connected to the sensing module 110 to selectively supply a calibration gas for setting when the sensing module 110 is operated. For example, the ash analyzer 120 according to the present embodiment supplies a calibration gas for calibrating the sensing module 110 at a specific time period, for example, 24 hours.

In addition, the ash analysis unit 120 receives the ash detection signal, analyzes the components of the exhaust gas, and transmits the temperature of the exhaust gas and the state of the sensing module 110 to the controller 150 . The controller 150 controls the sensor heating unit 130 and the exhaust gas inducing unit 140 according to a signal input from the ash analysis unit 120 .

The sensor heating unit 130 heats the sensing module 110 by supplying a high-temperature gas to the sensing module 110 to maintain the ash detection temperature of the sensing module 110 to be similar to the internal temperature of the exhaust duct 10 . Heat above the set temperature value. The sensor heating unit 130 is connected to the sensing module 110 through a gas supply line.

In addition, the sensor heating unit 130 selectively supplies the ash removal gas to the sensing module 110 to periodically remove the ash of the sensing module 110 .

The exhaust gas induction unit 140 continuously supplies the ejection gas to the sensing module 110 so that the exhaust gas flows into the sensing module 110 by the pressure difference between the inside of the sensing module 110 and the inside of the exhaust duct 10 . .

The ejection gas supplied from the exhaust gas induction unit 140 to the sensing module 110 circulates through the sensing module 110 and is discharged into the exhaust duct 10 to forcibly exhaust the exhaust gas inside the sensing module 110 . do.

The sensing module 110 is coupled to the exhaust duct 10 , the exhaust gas exhausted from the exhaust duct 10 is sucked by the exhaust gas induction unit 140 , and senses the ash of the exhaust gas.

The sensing module 110 includes a body 111 coupled to the exhaust duct 10 , an ash detection probe 113 provided in the body 111 to detect ash of exhaust gas, and exhaust for inflow of exhaust gas. It includes a gas inlet nozzle unit 115 and a gas discharge inducing unit 117 for circulating the ejection gas of the exhaust gas inducing unit 140 .

The main body 111 is coupled to the outer surface of the exhaust duct 10 of the boiler through bolts, and an exhaust gas circulation passage part 111a and an eject gas circulation passage part 111b for the circulation of exhaust gas are formed. In addition, the main body 111 is coupled to the ash detection probe 113 , and is connected to the ash analysis unit 120 , the sensor heating unit 130 , and the exhaust gas induction unit 140 through respective gas lines.

The exhaust exhaust gas circulation passage part 111a and the ejection gas circulation passage part 111b have one exhaust line so that exhaust gas and eject gas are respectively introduced and circulated through the body 111, and then mixed and discharged from the body 111. It communicates with the gas discharge induction unit 117 through the.

The ash detection probe 113 is coupled to the main body 111 to be inserted into the exhaust exhaust gas circulation passage part 111a and is connected to the ash analysis part 120, and exhaust gas is circulated inside and discharged. The ash detection probe 113 detects ash included in the exhaust gas.

The exhaust gas inlet nozzle unit 115 penetrates the gas discharge guide unit 117 to communicate with the exhaust gas circulation passage unit 111a and is coupled to the main body 111 to detect the exhaust gas transferred from the exhaust duct 10 as an ash detection probe. Transfer to (113).

The exhaust gas inlet nozzle 115 includes a gas inlet piping member 115a coupled to the main body 111 to be inserted into the exhaust duct 10, and for inducing the exhaust gas to the gas inlet piping member 115a. It includes a flow rate reducing cylinder member (115b).

One end of the gas inlet piping member 115a is coupled to the main body 111 to contact the ash detection probe 113 .

The flow rate reducing cylinder member 115b is formed to be larger than the diameter of the gas inlet piping member 115a, and is coupled to the other end of the gas inlet piping member 115a. A plurality of gas inlet holes 115c for introducing the exhaust gas are formed in the portion corresponding to the flow rate reducing cylinder member 115b in the transport direction of the exhaust gas. That is, while the flow rate of the exhaust gas flowing into the flow velocity reducing cylinder member 115b through the gas inlet hole 115c is reduced, it flows into the gas inlet pipe member 115a.

The gas discharge guide part 117 is formed in the form of a hollow body so that the gas inlet pipe member 115a penetrates, one end is coupled to the main body 111 and the other end is coupled to the exhaust duct 10 . The gas discharge inducing unit 117 communicates with the ejection gas circulation passage unit 111b, and discharges the ejection gas supplied from the exhaust gas inducing unit 140 to the exhaust duct 10 . At this time, the ejection gas supplied to the gas discharge induction unit 117 circulates through the ejection gas circulation passage unit 111b, then re-introduced into the gas discharge induction unit 117 to be discharged and at the same time through the gas discharge induction unit 117. It can be discharged directly to the exhaust duct (10).

The exhaust gas analysis system for a power plant according to the present invention configured as described above supplies a calibration gas to the sensing module 110 for detecting the ash of the exhaust gas before detecting the exhaust gas, and heats the ash detection probe 113 . Therefore, since it can be continuously managed, the reliability of the sensing module 110 can be improved and the period of use can be increased.

In addition, the exhaust gas analysis system for a power plant according to the present invention can effectively remove the ash attached to the sensing module 110 by supplying the ash removal gas to the sensing module 110, and the sensing module 110 through the supply of the ejection gas. ) to keep the inflow of exhaust gas uniform.

Although the present invention has been described with reference to the embodiment shown in the drawings, this is merely an example, and those skilled in the art to which various modifications and equivalent other embodiments are possible. will understand

Accordingly, the true technical protection scope of the present invention should be defined by the claims.

100: exhaust gas analysis system for power plant 10: exhaust duct
110: sensing module 111: body
111a: exhaust gas circulation passage part 111b: eject gas circulation passage part
113: ash detection probe 115: exhaust gas inlet nozzle unit
115a: gas inlet piping member 115b: flow rate reducing cylinder member
117: gas emission induction part 120: sorrow analysis part
130: sensor heating unit 140: exhaust gas induction unit
150: controller

Claims (2)

a sensing module coupled to the exhaust duct of the power plant and sensing the ash of the exhaust gas exhausted from the exhaust duct; an ash analysis unit connected to the sensing module to receive an ash detection signal from the sensing module to analyze the components of the ash and selectively supply a calibration gas for setting during operation; a sensor heating unit that heats the sensing module to maintain the ash detection temperature of the sensing module similar to the internal temperature of the exhaust duct and heats the sensing module above a set temperature value; and an exhaust gas inducing unit connected to the sensing module through a gas supply line to supply air to the sensing module so that the exhaust gas of the exhaust duct is sucked into the sensing module.
The sensing module may include: a body coupled to an outer surface of the exhaust duct, in which an exhaust gas circulation passage for circulation of the exhaust gas and an ejection gas circulation passage for circulation of ejecting air of the exhaust gas induction unit are formed; an ash detection probe coupled to the body so as to communicate with the exhaust gas circulation passage unit and detecting the ash contained in the exhaust gas; an exhaust gas inlet nozzle part coupled to the body to communicate with the exhaust gas circulation passage part and transferring the exhaust gas from the exhaust duct to the ash detection probe; and a hollow body shape to communicate with the exhaust gas circulation passage part and the ejection gas circulation passage part so that one end is coupled to the main body and the other end is coupled to the exhaust duct, and the exhaust gas and the ejection gas are exhausted from the exhaust gas. Including;
The exhaust gas circulation passage part and the ejection gas circulation passage part communicate with the gas exhaust induction part through one exhaust line so that the exhaust gas and the eject gas are respectively introduced and circulated in the main body, mixed and discharged from the main body and
The exhaust gas inlet nozzle unit may include a gas inlet pipe member coupled to the main body to be inserted into the exhaust duct; and a flow rate reducing cylinder member coupled to the other end of the gas inlet piping member to guide the exhaust gas to the gas inlet piping member.
The flow rate reducing cylinder member is formed to be larger than the diameter of the gas inlet piping member, and a plurality of gas inlet holes for introducing the exhaust gas are formed in a portion corresponding to the transport direction of the exhaust gas. gas analysis system. delete

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