KR101940502B1 - Contact type portable gas analyzer with separator for ash removal - Google Patents

Abstract

Disclosed is a contact-type portable gas analyzer with a separator for removing ash. The contact-type portable gas analyzer according to the present invention comprises: a pretreatment pipe inserted into a flange provided on an outer wall of a combustion facility from which exhaust gas is discharged, and extending into the combustion facility to extract some exhaust gas inside the combustion facility; and a gas analyzer mounted on the pretreatment pipe to analyze components of the exhaust gas. The pretreatment pipe includes: an inlet formed at one end of the pretreatment pipe to introduce exhaust gas; a pump for supplying suction force for extracting exhaust gas inside the combustion facility; an analyzer mounting unit provided at an upper end of the pretreatment pipe and having a gas analyzer mounted thereon; and a separator having one end fixed to an inner upper portion of the pretreatment pipe and the other end extended along a longitudinal direction of the pretreatment pipe, wherein a path through which the exhaust gas introduced into the pretreatment pipe reaches the gas analyzer is extended by the separator.

Description

TECHNICAL FIELD [0001] The present invention relates to a contact type portable gas analyzer having a separator for removing ash,

The present invention relates to a contact type portable gas analyzer having a separator for removing ash, and more particularly, to a contact type portable gas analyzer having a separator for removing ash, and more particularly, To a contact type portable gas analyzer.

In ships or on-land combustion facilities handling petrochemical-related products, various kinds of harmful substances which are harmful to human body during combustion process are generated through each process and discharged in the form of exhaust gas.

Such harmful substances include sulfur oxides, nitrogen oxides, carbon monoxide, sulfur dioxide, hydrogen chloride, and ammonia. Such harmful substances are not only harmful to the human body but also have a great environmental impact. Therefore, And is subject to legal / administrative restrictions.

Therefore, there is provided an analyzer for extracting a part of the exhaust gas discharged from the combustion facility and analyzing various components of the exhaust gas at a place where a large amount of exhaust gas is generated, such as a ship or a land combustion facility, I am taking action.

An analyzer for measuring the exhaust gas component can be classified into a contact type gas analyzer and a non-contact type gas analyzer. Figures 1 and 2 show an exemplary model of a contact gas analyzer and an exemplary model of a non-contact gas analyzer, respectively.

The contact type gas analyzer analyzes the composition of the exhaust gas in real time by directly contacting the gas sensor with the high temperature exhaust gas in the combustion facility.

The noncontact type gas analyzer extracts a part of high temperature exhaust gas in the combustion facility and sucks it into the measuring instrument provided at a specific place through a sampling line and cools the sucked exhaust gas in the pretreatment device installed in the measuring device, The components of the exhaust gas are analyzed by a gas sensor mounted inside the measuring device.

In recent years, the compatibility of exhaust gas is the most accurate to measure directly in real time in the field, so contact type gas analyzer is a preferred trend.

However, the contact type gas analyzer developed up to now does not have a pretreatment device. When the gas sensor is directly contacted with the exhaust gas without the pretreatment device to measure the component, the gas sensor may be damaged by the high temperature heat of the exhaust gas, and foreign substances such as ash contained in the exhaust gas may be removed Which precludes accurate detection of the gas component.

An object of the present invention is to provide a contact type portable gas analyzer capable of measuring exhaust gas components in a combustion facility in real time in the field, and removing foreign matter such as ashes contained in exhaust gas to accurately measure components.

In order to accomplish the above object, the present invention provides a pretreatment piping which is inserted into a flange provided on an outer wall of a combustion facility through which exhaust gas is discharged and extends into the combustion facility to extract a part of exhaust gas from the combustion facility. And a gas analyzer mounted on the pretreatment pipe for analyzing a component of the exhaust gas, wherein the pretreatment pipe comprises: an inlet formed at one end of the pretreatment pipe and through which the exhaust gas flows; A pump for providing a suction force for extracting exhaust gas from the combustion facility; An analyzer mounting part provided at an upper end of the pretreatment pipe and equipped with the gas analyzer; And a separator having one end fixed to the upper portion of the interior of the pretreatment pipe and the other end extending along the longitudinal direction of the pretreatment pipe, wherein the exhaust gas introduced into the pretreatment pipe by the separator reaches the gas analyzer A contact type portable gas analyzer provided with a separator for removing ash, characterized in that the path is extended.

Wherein the separator comprises: a first separator provided below the analyzer mounting portion; And a second separator spaced apart from the first separator. In the course of transferring the exhaust gas flowing into one end of the pretreatment pipe to the other end of the pretreatment pipe, the ash contained in the exhaust gas has a gravity And the exhaust gas from which the ash is removed can be supplied to the gas analyzer through the spaced space between the first separator and the second separator.

The first separator and the second separator may be provided such that one end thereof is bent upwardly and the upwardly bent portion is inclined toward the inlet.

Alternatively, the first separator and the second separator may be formed in an S-shaped configuration, and may include a bent portion bent at a lower end thereof so as to be inclined downward in a direction that obstructs the flow of exhaust gas.

The first separator and the second separator may include a circulation hole through which the exhaust gas at an upper portion can be circulated downward.

The first separator and the second separator may include an obstruction plate for preventing the exhaust gas flowing into the inlet port from being directly introduced into the circulation hole.

The pretreatment pipe may further include a foreign matter removing unit provided at a lower portion of the pretreatment pipe to remove ash that has fallen to the bottom of the pretreatment pipe.

The present invention may further include a coupling flange for supporting the pretreatment pipe and engaging with the flange.

The gas analyzer includes a gas sensor that is in direct contact with the exhaust gas to measure the component, and the gas sensor can be inserted into the pretreatment pipe by the analyzer mount.

According to the present invention, it is possible to directly extract the exhaust gas from the combustion facility and directly measure the component from the gas analyzer installed outside the combustion facility, so that it is possible to analyze the composition of the exhaust gas in real time on site.

The present invention has the effect of improving the durability of a gas sensor which can accurately measure components by removing foreign substances such as ashes contained in the exhaust gas before the exhaust gas reaches the gas analyzer and in direct contact with the exhaust gas.

The present invention is very portable with a method of directly contacting the gas sensor with the exhaust gas.

In addition, the present invention can prevent the gas sensor of the gas analyzer from being damaged by the high-temperature heat inside the combustion facility because the attachment portion of the gas analyzer is located outside the combustion facility, The gas analyzer can be checked and maintained at any time while it is still running.

1 is a diagram showing an exemplary model of a conventional contact gas analyzer.
2 is a diagram showing an exemplary model of a conventional noncontact type gas analyzer.
3 is a view showing a flange attached to a conventional combustion facility.
4 is a view showing a contact type portable gas analyzer according to the present invention.
Fig. 5 is a view showing a first embodiment of the present invention, wherein (a) shows a pretreatment pipe provided with an L-shaped separator, and (b) shows only an L-shaped separator.
6 is a view showing a second embodiment of the present invention, wherein (a) is a view showing a pretreatment pipe provided with an S-shaped separator, and (b) is a view showing only an S-shaped separator.
7 is a diagram showing an actual developed product of the contact type portable gas analyzer according to the present invention.

In order to fully understand the present invention, operational advantages of the present invention, and objects achieved by the practice of the present invention, reference should be made to the accompanying drawings and the accompanying drawings which illustrate preferred embodiments of the present invention. Like reference symbols in the drawings denote like elements.

Hereinafter, preferred embodiments of the present invention will be described with reference to the accompanying drawings. In addition, the following examples can be modified in various forms, and the scope of the present invention is not limited to the following examples.

FIG. 3 is a view showing a flange attached to a conventional combustion facility, FIG. 4 is a view showing a contact type portable gas analyzer according to the present invention, FIG. 5 is a view showing a first embodiment of the present invention, FIG. 7 is a view showing an actual developed product of the contact type portable gas analyzer according to the present invention.

Referring to FIG. 3, a plurality of flanges provided for various purposes are provided on an outer wall of a conventional combustion facility, and these flanges are blocked by opening / closing means that can be detached when not in use.

The present invention provides a contact type portable gas analyzer capable of extracting a part of exhaust gas in a combustion facility using a flange installed in an existing combustion facility and analyzing the component.

4 to 7, the contact type portable gas analyzer according to the present invention is inserted into a flange 101 provided on an outer wall of a combustion facility 100 through which exhaust gas is discharged A pretreatment pipe (200) for extracting some exhaust gas in the combustion facility (100); And a gas analyzer (300) mounted on the pretreatment pipe (200) and analyzing the components in the exhaust gas extracted by the pretreatment pipe (200).

The combustion facility 100 may be a facility for discharging exhaust gas, such as an exhaust duct, and a one-way flow of the exhaust gas is formed therein.

The pretreatment pipe 200 is inserted into a flange 101 provided at an outer wall of the combustion facility 100 at one end and extends into the combustion facility 100.

The pretreatment pipe 200 may be supported by the coupling flange 201 and the coupling flange 201 may be bolted to the flange 101 so that the pretreatment pipe 200 may be stably inserted and supported within the combustion facility 100. [ .

A pump 202 is provided at the other end of the pretreatment pipe 200 to provide a suction force by which a part of the exhaust gas in the combustion facility 100 is sucked into the pretreatment pipe 200. The exhaust gas sucked into the pretreatment pipe 200 And forcedly discharged to the atmosphere by the pump 202.

The pretreatment pipe 200 may be made of a metal pipe and an inlet 203 through which the exhaust gas flows may be formed at one end of the pretreatment pipe 200 inserted into the combustion facility 100.

One end of the pretreatment pipe 200 may be inclined so that the exhaust gas can be easily guided toward the inlet 203. The inlet 203 is formed on the pretreatment pipe 200 facing the flow of the exhaust gas and may have a round hole shape.

At the upper end of the pretreatment pipe 200, an analyzer mounting part 204 to which the gas analyzer 300 is mounted is provided. The analyzer mounting portion 204 may be provided in such a form that the gas sensor 301 of the gas analyzer 300 can be inserted into the pre-treatment pipe 200.

Separators 205 and 206 may be installed in the upper part of the interior of the pretreatment pipe 200.

The separators 205 and 206 separate the lower space of the analyzer mounting portion 204 on which the gas sensor 301 is mounted from the internal space of the pretreatment pipe 200 so that the exhaust gas flowing into the inlet 203 flows into the gas sensor 301, So that it can not be reached directly.

As shown in Figs. 5 and 6, the separators 205 and 206 prevent the exhaust gas from reaching the gas sensor 301 side from the inlet 203, divide the layer of the inner space of the pretreatment pipe 200, By extending the path through which the gas reaches the gas sensor 301 side, it is ensured that sufficient time is allowed for foreign matter such as ash contained in the exhaust gas to fall.

The separators 205 and 206 include a first separator 205 provided below the analyzer attachment portion 204 and a second separator 206 spaced apart from the first separator 205.

One end of the first separator 205 is fixed to the upper part of the pretreatment pipe 200 to the inlet 203 side of the analyzer mounting part 204 and the other end of the first separator 205 is connected to the inside of the pretreatment pipe 200 along the longitudinal direction of the pretreatment pipe 200 .

In the process of being transferred to the other end side of the pretreatment pipe 200, the exhaust gas flowing into the inlet 203 is dropped by the gravity of foreign matter such as ash contained in the exhaust gas, and the exhaust gas from which the foreign substance is removed is discharged to the first separator 205 and the second separator 206 to the gas sensor 301 side.

Therefore, the exhaust gas reaching the gas sensor 301 can maintain a uniform gas phase from which the foreign substance is removed, and therefore more accurate component analysis by the gas sensor 301 can be performed.

Referring to Figs. 5 (b) and 6 (b), the separators 205 and 206 may include a circulation hole h for circulating the exhaust gas.

The circulation holes h allow the upper and lower portions of the separators 205 and 206 to communicate with each other so that the exhaust gas flowing into the gas sensor 301 side is circulated smoothly without stagnation.

Further, the separators 205 and 206 may further include a baffle plate f1 provided so as to be inclined downward in the direction to obstruct the flow of the exhaust gas in the vicinity of one end. Accordingly, the separators 205 and 206 may be provided in a substantially Y-shape that is divided by the upwardly facing end and the downwardly facing baffle f1.

The obstruction plate f1 prevents the exhaust gas flowing through the inlet 203 from flowing into the circulation hole to prevent the exhaust gas from interfering with the circulation of the exhaust gas. When the exhaust gas entering the inlet 203 flows into the circulation hole h, exhaust gas in the space above the separators 205 and 206 may become stagnant.

The obstruction plate f1 can also serve to increase the chance of collision of the foreign substances in the extracted exhaust gas transferred into the pretreatment pipe 200 through the inlet 203. [ As a result, the removal efficiency of the foreign matter in the exhaust gas is improved, and the durability of the gas sensor 301 in direct contact with the exhaust gas is significantly increased.

The separators 205 and 206 applied to the present invention may be provided in two forms, L-shaped separators 205-L and 206-L and S-shaped separators 205-S and 206-S.

5, one end of each of the L-shaped separators 205-L and 206-L has an upwardly bent shape, and this bent portion is provided so as to be inclined as one end of the pretreatment pipe 200. As shown in FIG.

The inclined one end of the first separator 205-L smoothes the flow of the exhaust gas flowing into the inlet 203 and the inclined one end of the second separator 206-L is connected to the gas sensor 301 in the exhaust gas flow direction.

The space between the first separator 205-L and the upper surface of the pretreatment pipe 200 is narrower than the space between the first separator 205-L and the lower surface of the pretreatment pipe 200, The flow of the exhaust gas can be accelerated when flowing into the gas sensor 301 side through the spaced space between the first separator 205-L and the second separator 206-L.

At this time, in the process of flowing the exhaust gas through the spaced apart spaces, the impurities in the exhaust gas collide with the inclined one end portion of the second separator 206-L to fall, thereby improving the removal efficiency of foreign matter in the exhaust gas.

Next, referring to FIG. 6, the S-shaped separators 205-S and 206-S are curved in an S-shape as a whole.

The S-shaped separators 205-S and 206-S are introduced into the inlet 203 by one bent end of the first separator 205-S, similarly to the L-shaped separators 205-L and 206- And the flow of the exhaust gas led to the gas sensor 301 is smooth by the bent one end of the second separator 206-S.

In the process of flowing the exhaust gas through the spaced space between the first separator 205-S and the second separator 206-S, the second separator 206- So that the foreign matter removal rate in the exhaust gas is improved.

In addition, the S-shaped separators 205-S and 206-S have a bent shape such that the other end thereof is inclined downward in a direction in which the flow of the exhaust gas is disturbed. Hereinafter, this bent end is referred to as a bent portion f2 for convenience.

The S-shaped separators 205-S and 206-S can more effectively remove the foreign matter in the exhaust gas by the bent portion f2. The S-shaped separators 205-S and 206-S further include a bent portion f2 in addition to the structure of the above-described baffle plate f1 to maximize the foreign matter removal effect in the exhaust gas. It goes without saying that the configuration of the bent portion f2 may be applied to the other ends of the L-shaped separators 205-L and 206-L.

At the lower end of the pretreatment pipe 200, a foreign matter removing unit 207 for removing foreign substances falling to the bottom of the pretreatment pipe 200 is provided. The foreign substance removing unit 207 may be provided to be openable and closable by the opening and closing member 208.

For example, the foreign material removing unit 207 may be a hole through which the bolt can be fastened, and the opening and closing member 208 may be a bolt. When the measurement of the composition of the exhaust gas is completed, the foreign substance removing unit 207 is opened by loosening the bolts fastened to the holes, thereby removing foreign substances accumulated on the bottom of the pretreatment pipe 200.

That is, in the present invention, the pretreatment pipe 200 is used to remove foreign substances such as ashes contained in the exhaust gas before the exhaust gas reaches the gas analyzer 300, thereby improving the accuracy of the component measurement. As shown in Fig.

The gas analyzer 300 includes a gas sensor 301 inserted into or attached to the analyzer mounting portion 204 provided in the upper portion of the pretreatment pipe 200 and in direct contact with the exhaust gas flowing in the pretreatment pipe 200, A portable analyzer 302 for receiving and analyzing signals measured by the portable analyzer 302 and an electronic device 303 for receiving data analyzed by the portable analyzer 302 and performing a data log.

The gas sensor 301 may be a contact type sensor that directly contacts the exhaust gas to measure the component. For example, the gas sensor 301 may be a sensor for detecting change in electrical resistance due to gas adsorption as an electrochemical gas sensor. However, the present invention is not limited thereto, and various known contact gas sensors can be applied.

The portable analyzer 302 analyzes the signal transmitted from the gas sensor 301 and transmits the analyzed data to the electronic device 303. The portable analyzer 302 can be connected to an electronic device 303 such as a PC, a tablet PC, or a smart phone through a USB communication cable.

The electronic device 303 displays the data transmitted through the USB communication cable on a monitor and performs a data log.

4 to 7, a method of operating the contact type portable gas analyzer according to the present invention will be described.

When the analysis of the composition of the exhaust gas is started by the contact type gas analyzer according to the present invention, the opening and closing means blocking the flange 101 provided in the combustion facility 100 is removed, and the pretreatment pipe 200 is attached to the flange 101 .

The pre-treatment pipe 200 can be stably inserted and supported inside the combustion facility 100 by bolt-coupling the flange 101 with the coupling flange 201 that supports the pre-treatment pipe 200.

When the pump 202 installed in the pretreatment pipe 200 is operated while the pretreatment pipe 200 is inserted into the combustion facility 100, some exhaust gas in the combustion facility 100 is supplied to one end of the pretreatment pipe 200 Is drawn into the formed inlet 203 and then discharged to the atmosphere through the other end of the pretreatment pipe 200.

As the exhaust gas flowing into the pretreatment pipe 200 flows through the interior of the pretreatment pipe 200, foreign substances such as ashes contained in the exhaust gas are dropped by the separator 205 and removed, and only a uniform gas phase exhaust gas Is transferred to the gas analyzer 300 mounted on the upper end of the pretreatment pipe 200.

After the composition of the exhaust gas is analyzed by the gas analyzer 300, the operation of the pump 202 is stopped and the foreign matter removing unit 207 provided at the lower end of the pretreatment pipe 200 is opened to open the bottom of the pretreatment pipe 200 It is possible to remove the foreign matter accumulated in the air.

According to the present invention, since a part of exhaust gas is extracted from the combustion facility 100 and the component can be directly measured by the gas analyzer 300 installed outside the combustion facility 100, the component analysis of the exhaust gas in real- It is possible.

The present invention can precisely measure the component by removing foreign substances such as ashes contained in the exhaust gas before the exhaust gas reaches the gas analyzer 300 and improve the durability of the gas sensor 301 in direct contact with the exhaust gas It is effective.

The present invention is very portable with a method of directly contacting the gas sensor with the exhaust gas.

Since the gas analyzer 300 is installed outside the combustion facility 100, the gas sensor 301 of the gas analyzer 300 is damaged by the heat of the high temperature inside the combustion facility 100 It is possible to frequently check and maintain the gas analyzer 300 in a state where the existing equipment is continuously operated even when the gas analyzer 300 is abnormally generated.

While the present invention has been particularly shown and described with reference to exemplary embodiments, it is to be understood that the invention is not limited to the disclosed exemplary embodiments, but, on the contrary, And should not be construed as limiting the scope of the invention.

100: Combustion facility 101: Flange
200: Pretreatment piping 201: Coupling flange
202: Pump 203: Inlet
204: analyzer attachment unit 205: first separator
206: Second separator 207: Foreign matter removal
208: opening / closing member
300: Gas analyzer 301: Gas sensor
302: Gas analyzer 303: Electronic device
h: Circular hole
f1: interference plate f2:

Claims (9)

A pretreatment pipe inserted into a flange provided on an outer wall of a combustion facility through which exhaust gas is discharged to extend into the combustion facility to extract a part of exhaust gas from the combustion facility; And
And a gas analyzer mounted on the pretreatment pipe for analyzing a component of the exhaust gas,
The pre-
An inlet port formed at one end of the pretreatment pipe and through which exhaust gas flows;
A pump for providing a suction force for extracting exhaust gas from the combustion facility;
An analyzer mounting part provided at an upper end of the pretreatment pipe and equipped with the gas analyzer; And
And a separator having one end fixed to the inner upper portion of the pretreatment pipe and the other end extending along the longitudinal direction of the pretreatment pipe,
The path through which the exhaust gas flowing into the pretreatment pipe reaches the gas analyzer is extended by the separator,
Wherein the ash contained in the exhaust gas is dropped by gravity while the exhaust gas flowing into one end of the pretreatment pipe is transferred to the other end of the pretreatment pipe.
Contact type portable gas analyzer equipped with a separator for ash removal.
The method according to claim 1,
Wherein the separator comprises:
A first separator provided below the analyzer mounting portion; And
And a second separator spaced apart from the first separator,
The ash contained in the exhaust gas falls due to gravity and the exhaust gas from which the ash is removed flows through the first separator and the second separator, And the gas is supplied to the gas analyzer through a spaced space between the second separators.
Contact type portable gas analyzer equipped with a separator for ash removal.
The method of claim 2,
Characterized in that the first separator and the second separator are formed in an L-shape in which one end is folded upward and the upwardly bent portion is inclined toward the inlet.
Contact type portable gas analyzer equipped with a separator for ash removal.
The method of claim 2,
Characterized in that the first separator and the second separator are formed in a slender S shape and include bent portions bent at the other end so as to be inclined downward in a direction that interferes with the flow of the exhaust gas.
Contact type portable gas analyzer equipped with a separator for ash removal.
The method according to claim 3 or 4,
Characterized in that the first separator and the second separator include a circulation hole through which the exhaust gas in the upper portion can be circulated downward.
Contact type portable gas analyzer equipped with a separator for ash removal.
The method of claim 5,
Wherein the first separator and the second separator include an obstruction plate for preventing the exhaust gas flowing into the inlet port from being directly introduced into the circulation hole.
Contact type portable gas analyzer equipped with a separator for ash removal.
The method of claim 2,
The pre-
Further comprising a foreign matter removing unit provided at a lower portion of the pretreatment pipe to remove ash falling down to the bottom of the pretreatment pipe.
Contact type portable gas analyzer equipped with a separator for ash removal.
The method of claim 2,
And a coupling flange for supporting said pretreatment tubing and engaging said flange,
Contact type portable gas analyzer equipped with a separator for ash removal.
The method of claim 2,
The gas analyzer includes a gas sensor for measuring the component in direct contact with the exhaust gas,
Wherein said gas sensor is inserted into said pretreatment tubing by said analyzer mounting.
Contact type portable gas analyzer equipped with a separator for ash removal.

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