KR20130026161A - 4-way sampling valve used in the by-pass line and real-time sampling device that contains it - Google Patents

Abstract

PURPOSE: A four-way sampling valve for a bypass line and a real-time sampling device including the same are provided to inject inactive gas for cleaning and to extract chemical substances on a real time basis by removing a plurality of control valves. CONSTITUTION: A four-way sampling valve(100) comprises a body(110), a bypass hole(120), a branch hole(130), an extraction hole(140), a gas injection hole(150) and a branch hole opening/closing unit(160). The body is made of a metal material and is installed in a sampling bypass line. The bypass hole penetrates the body and provides a fluid passage which is aligned with the sampling bypass line in order to circulate the chemical substances which is flowed through the sampling bypass line. The branch hole is formed in the body. One side of the branch hole is connected with the bypass hole and the other side is connected with the extraction hole. The extraction hole flows in the chemical substances by connecting with the branch hole; flow in inactive gas for cleaning through the gas injection hole; and is connected to the outside of the body. The gas injection hole provides a gas fluid passage for injecting the inactive gas into the extraction hole and is connected to the outside of the body. The opening and closing unit of the branch hole opens and closes the branch hole by crossing the extraction hole.

Description

4-WAY SAMPLING VALVE USED IN THE BY-PASS LINE AND REAL-TIME SAMPLING DEVICE THAT CONTAINS IT}

The present invention is to extract a sample of the product produced in the chemical plant or intermediates occurring in the intermediate process, in particular to extract the sample through the bypass (by-pass) line in order to safely extract a sample of toxic chemicals To a valve and a sampling device comprising the same

Sampling made through a conventional sampling bypass line extracts a sample in a main line 1 through which liquid chemical 10 passes, as schematically shown in the figure showing a pipe and a valve for extracting the conventional sample. A sampling bypass line 2 is formed to extract the chemicals introduced into the sampling bypass line 2 and sample the same.

In general, the sampling bypass line (2) consists of a T-branch (3) and a valve (4), and a holder in a line branched from the sampling bypass line (2) to the T-branch (3). The sampling unit 5 consisting of and the storage container is combined to extract the chemical substance 10.

That is, when the valve 4 of the sampling bypass line 2 is completely opened, the liquid chemical 10 to be extracted is extracted from the main line 1 through the sampling bypass line 2. It is distributed, branched from the T-branch 3, flowed into the storage container of the sampling unit 5, and sampled.

Therefore, the conventional sample extraction apparatus as shown in FIG. 1 passes through the chemical currently being produced in the sampling bypass line 2, that is, the current main line 1, before sampling in order to extract the correct sample. Chemicals (10) to be distributed.

In other words, in order to accurately measure the state of the presently produced products or intermediates, samples of liquid chemicals currently passing through the main line 1 must be extracted.

However, since the previously predetermined liquid chemical remains in the sampling bypass line 2, in order to extract an accurate sample, the sampling bypass line 2 is opened before the sample is extracted and the sampling bypass line 2 is opened. The remaining chemicals must be pushed out to the main line (2) and the currently produced chemicals to be sampled must pass through the sampling bypass line (2).

Therefore, the conventional sampling extraction apparatus has a problem that it is difficult to accurately sample in real time, and in the configuration of the sampling bypass line (2), the use of a large number of valves has the trouble of operation, and the failure of the valve (3) and the like There is a problem that is difficult to manage due to the increase in the number of defects, and there is a problem that the reliability of the sample is lowered because the possibility of the residual material is generated by using a plurality of valves.

In addition, when chemicals remain in the sampling bypass line 2, there is a problem in that it is necessary to discharge and dispose of them, and a waste cost is generated, and a problem of discharging environmental pollutants occurs.

In addition, a worker extracting a sample has a problem of being exposed to a large amount of toxic gas generated in the process of discarding the liquid chemicals and extracting the sample, and the working environment in the factory by the large amount of toxic gas as well as the atmosphere There is a problem in that the toxic gas is radiated to pollute the atmosphere.

In order to solve the problem of toxic gas leakage and the disposal of chemicals, a conventional "sealing sample extraction device" (Application No. 20-2003-0023581) has been disclosed as a sample extraction device. The bypass line as described above has a problem that is difficult to apply, and structurally difficult to maintain.

An object of the present invention is to provide a sampling valve which is designed to solve the above problems and installed in a sampling bypass line to extract a sample in real time.

In addition, an object of the present invention is to provide a sampling valve capable of directly introducing an inert gas for cleaning through a valve.

In addition, it is an object of the present invention to provide a sample extraction device including a sampling valve such that no toxic gas is discharged and no chemicals are generated and samples can be extracted in real time.

In addition, an object of the present invention is to provide a sampling device that is easily replaced with a sampling tube and a gas discharge tube that are inserted into a storage container in which replacement is frequently performed.

In order to achieve the problem to be solved by the present invention as described above, the four-way sampling valve for the bypass line of the present invention is coupled to the line through which the liquid chemical passes in order to sample the liquid chemical produced in the chemical plant. A sampling valve installed in a sampling bypass line, comprising: a body made of a metal material and installed in the sampling bypass line; A bypass hole formed through the main body and providing a flow path formed in parallel with the sampling bypass line so that chemicals for the purpose of extraction flowing through the sampling bypass line are circulated; A branching hole formed in the main body and having one side communicating with the bypass hole and the other side communicating with the extraction hole; The extraction hole communicates with the branch hole and the chemicals are introduced through the branch hole, or the inert gas for cleaning is introduced through the gas injection hole, and is in communication with the outside of the main body; A gas injection hole communicating with the extraction hole and providing a gas flow path through which the inert gas injected for cleaning the extraction hole is injected into the extraction hole and communicating with the outside of the main body; And a branch hole opening and closing portion for opening and closing the branch hole across the extraction hole.

In addition, the main body further includes a protruding coupling portion that extends in a cylindrical shape from the main body at the position of the extraction hole and the thread is formed on the outside, wherein the extraction hole is in continuous communication with the outside of the main body to the engaging portion It is characterized by;

In addition, the branch opening opening portion is screwed to the main body to open and close the branch hole forward or backward, the plugging head is inserted into the branch hole to open and close the branch hole; and the rod coupled to the plugging head and the main body; and the Handle for rotating the rod; characterized in that consisting of.

The real-time sampling device of the present invention using the valve according to the present invention as described above is formed through the main body and the main body installed in the sampling bypass line, and the chemicals for the purpose of extraction flowing through the sampling bypass line are distributed. A bypass hole providing a flow path formed in parallel with the sampling bypass line and the main body so that one side is in communication with the bypass hole and the other side is in communication with the extraction hole and the branch hole is in communication with the branch hole. A substance is introduced or an inert gas for cleaning is introduced through a gas injection hole, and an extraction hole communicating with the outside of the main body and an inert gas communicated with the extraction hole to be injected into the extraction hole are injected into the extraction hole. It provides a gas flow path to the outside of the body and Across the gas injection hole and the ball to be extracted barrel bypass line Four-way sampling valve comprising a closing portion for opening and closing the bungigong bungigong; A check valve coupled to a gas injection hole of the foreway sampling valve for the bypass line to allow injection of a septic gas for cleaning; Combined with the line four-way sampling valve and filter, injecting the chemical or inert gas injected through the by-line four-way sampling valve to the storage container, and discharges the gas in the storage container to the external filter side Injection manifold set; A filter coupled to the injection manifold set and connected to the gas discharge pipe; A storage container holder coupled to the injection manifold set and fixing the storage container inserted therein; And a storage container inserted into the storage container holder and having an inlet formed of an elastic material, through which the sampling pipe and the gas discharge pipe of the injection manifold set are inserted.

In addition, the injection manifold set is a manifold consisting of a sampling pipe connection hole coupled to the line foreway sampling valve to connect the extraction hole and the sampling pipe, and a gas discharge pipe connection hole coupled to the filter to connect the gas discharge pipe and the filter. main body; A sampling tube coupled to the manifold body and connected to the sampling tube connection hole and inserted into the storage container; A gas discharge pipe coupled to the manifold body and connected to the gas discharge pipe connection hole and inserted into the storage container; A pipe fixing part through which the sampling pipe and the gas discharge pipe penetrate and are coupled to the manifold body and the fastening bolt to fix the sampling pipe and the gas discharge pipe; And a sealing located between the manifold body and the pipe fixing part to prevent leakage of chemicals and gases being extracted.

In addition, the sealing is characterized in that it further comprises a Teflon sealing.

In addition, the sampling pipe connection hole and the gas discharge pipe connection hole of the manifold body is formed with a sampling pipe insertion groove and the gas discharge pipe insertion groove, the sampling tube and the gas discharge pipe is formed with an insertion head is inserted into each of the insertion groove; It is characterized by.

In addition, the filter is made of a carbon material;

Through the four-way sampling valve for the bypass line according to the present invention by removing a plurality of conventional control valves in real time to extract chemicals, inert gas for cleaning, sampling valves to prevent the discharge of chemicals that are discarded Has the effect of providing.

In addition, there is an effect that can be extracted in real time through a real-time sampling device including a foreway sampling valve for the bypass line according to the present invention. In addition, by injecting the inert gas for cleaning directly through the valve has an effect that can easily clean the extraction line from which the chemical is extracted.

In addition, there is no effect that the toxic gas is not discharged and the chemicals discarded are not generated and the sample can be extracted in real time.

In addition, it is easy to replace the sampling tube and the gas discharge tube is inserted into the storage container is frequently replaced.

1 is a view showing a pipe and a valve for extracting a conventional sample,
Figure 2 shows a four-way sampling valve for the bypass line of the present invention,
Figure 3 is a detailed view of the four-way sampling valve for the bypass line of the present invention,
4 is a view showing a real-time sampling device including a four-way sampling valve for the bypass line of the present invention;
5 is a view for explaining the injection manifold set of the real-time sampling device including the four-way sampling valve for the bypass line of the present invention;
6 is a view for explaining the injection manifold set of the real-time sampling device including the four-way sampling valve for the bypass line of the present invention in detail.

The following detailed description of the invention refers to the accompanying drawings, which illustrate, by way of illustration, specific embodiments in which the invention may be practiced. These embodiments are described in sufficient detail to enable those skilled in the art to practice the invention. It should be understood that the various embodiments of the present invention are different, but need not be mutually exclusive. For example, specific shapes, structures, and characteristics described herein may be implemented in other embodiments without departing from the spirit and scope of the present invention with respect to one embodiment. In addition, it is to be understood that the location or arrangement of individual components within each disclosed embodiment may be changed without departing from the spirit and scope of the invention. The following detailed description, therefore, is not to be taken in a limiting sense, and the scope of the present invention is defined only by the appended claims, along with the full scope of equivalents to which such claims are entitled. In the drawings, like reference numerals refer to the same or similar functions throughout the several views.

Hereinafter, preferred embodiments of the present invention will be described in detail with reference to the accompanying drawings so that those skilled in the art can easily implement the present invention.

2 shows a four-way sampling valve for a bypass line according to the present invention, as shown in FIG. 1, a four-way sampling valve 100 for the bypass line according to the present invention. And the configuration consisting of a plurality of valves 4 can be replaced by a foreway sampling valve 100 for the bypass line.

That is, the sampling line composed of the plurality of valves 4 and the T-branch 3 is replaced with the foreway sampling valve 100 for the bypass line to extract the liquid chemical 10 in real time.

When describing the bypass line foreway sampling valve 100 in detail, Figure 3 as a detailed view of the bypass line foreway sampling valve of the present invention, the liquid chemical produced in the chemical plant In the sampling valve installed in the sampling bypass line coupled to the line through which the liquid chemical passes in order to sample the body, the body 110, the bypass hole 120, the branch hole 130, the extraction hole 140 , The gas injection hole 150 and the branch opening opening 160.

The main body 110 is made of a metal material and is coupled to the sampling bypass line 2.

The coupling between the main body 110 and the pipe of the sampling bypass line 2 may be directly screwed or coupled through a nipple.

The bypass hole 120 is formed through the main body 110, as shown in Figure 3 (a) and Figure 3 (b) showing a vertical cross-section of the main body 100, sampling bypass line (2) It provides a flow path formed in parallel with the sampling bypass line (2) so that the chemical for the purpose of extraction flowing through the).

That is, the sampling bypass line 2 and the bypass hole 120 are connected to build a sampling bypass line 2 through which the chemical substance 10 passes in real time together with the main line 1.

The branch hole 130 is formed in the main body 110 as shown in Figure 3 (b) or (c) and one side is in communication with the bypass hole 120 and the other side is in communication with the extraction hole 140 Is formed.

That is, the branch hole 130 is for extracting the chemical substance 10 flowing in the bypass hole 120 in real time, and when the branch hole 130 is opened by the branch opening opening 160, the real time The chemical 10 flowing into the bypass hole 120 is introduced into the extraction hole 140.

As shown in FIG. 3 (b) or (c), the extraction hole 140 communicates with one side of the branch hole 130 and the gas injection hole 150 and the other side communicates with the outside of the main body 10. .

Therefore, the chemicals 10 are introduced into the branch holes 130 through the branch holes 130, or an inert gas for cleaning is introduced through the gas injection hole 150 to inert the chemicals or the cleaner to the outside. The gas is discharged to the outside of the main body 10.

Preferably, the main body 110 further includes a protruding coupling portion 112 extending in a cylindrical shape from the main body 110 at the position of the extraction hole 140 and having a thread formed therein, and the extraction hole 140. ) Is connected to the outside of the main body 110 is continuous to the protrusion coupling portion (112).

The gas injection hole 150 is in communication with the extraction hole 140 as shown in Figure 3 (b) or (c) is inert gas injected for the cleaning of the extraction hole 140 is the extraction hole ( 140 to provide a gas flow path for injection.

That is, the gas injection hole 150 connects the outside of the main body 110 and the extraction hole 140 to the inert gas injected from the outside of the main body 110 through the gas injection hole 150. 140).

The branch opening and closing part 160 opens and closes the branch hole 130 across the extraction hole 140 as shown in FIG. 3 (b) or (c).

That is, the branch opening opening 160 may be formed in various forms and structures that can open and close the branch hole 130 as a means for opening and closing the branch hole 130 for the extraction of the chemical (10).

Preferably, the plugging head 162 and the plugging head are inserted into the branch hole 130 to open and close the branch hole 130 by opening and closing the branch hole 130 by forward and backward by screwing with the screw groove formed in the main body 110. A rod 164 coupled with the 162 and screwed with the main body 110, and a handle 166 for rotating the rod 164.

In this case, the gas injection hole 150 is not closed even when the branch hole opening and closing part 160 is closed as shown in FIG. 3 (b).

That is, the branch opening and closing unit 160 only opens and closes the branch hole 130 and does not affect the gas injection hole 150.

As described above, the present invention describes a four-way sampling valve 100 for the bypass line, and a real-time sampling apparatus including the four-way sampling valve for the bypass line will now be described.

4 shows a real-time sampling device including the four-way sampling valve for the bypass line, the four-way sampling valve 100, the check valve 200, the injection manifold set 300 for the bypass line. ), The filter 400, the storage container holder 500 and the storage container 600.

The bypass line four-way sampling valve 100 is formed through the main body 110 and the main body 110 installed in the sampling bypass line 2, as shown in FIGS. The bypass hole 120 and the main body providing a flow path formed in parallel with the sampling bypass line 2 so that the chemicals 10 for the purpose of extraction flowing through the sampling bypass line 2 are distributed. It is formed in 110 and one side is in communication with the bypass hole 120 and the other side is formed to communicate with the branch hole 130 and the branch hole 130 is formed to communicate with the chemical through the branch hole 130 A substance is introduced or an inert gas for cleaning is introduced through the gas injection hole 150, and the extraction hole 140 and the extraction hole 140 communicating with the outside of the main body 110 are communicated with the extraction hole ( 140, the inert gas injected for cleaning Branch opening and closing unit 160 for providing a gas flow path to be injected into the outlet 140 and opening and closing the branch hole 130 across the gas injection hole 150 and the extraction hole 140 in communication with the outside of the main body 140 It is made, including.

In addition, the foreline sampling valve 100 for the bypass line has a configuration of various sampling valves as described above.

The check valve 200 is coupled to the gas injection hole 150 of the four-way sampling valve 100 for the bypass line as a means for allowing only one flow.

That is, between the gas distribution control valve 710 coupled to the gas line 700 in which the inert gas deficient in reactivity, such as nitrogen, carbon dioxide, argon gas, and the like, passes through the foreway sampling valve 100 for the bypass line. Positioned to allow the inert gas for cleaning in the gas line 700 to flow into the foreway sampling valve 100 for the bypass line, and the gas line 700 at the foreway sampling valve 100 for the bypass line. Prevent outflow to the side.

Combined with the gas injection hole 150 of the by-pass sampling valve 100 for the bypass line inert gas for cleaning the inert gas into the by-pass sampling valve 100 for the bypass line for the bypass line The four-way sampling valve 100 and the injection manifold set and sampling tube are cleaned.

Therefore, when the gas flow control valve 710 of the gas line 700 is opened, the inert gas from the gas line 700 to the foreway sampling valve 100 for the bypass line via the check valve 200. Is injected.

The inert gas injected into the bypass line foreway sampling valve 100 includes the injection manifold set 300, the sampling pipe 320, the storage container 600, the gas discharge pipe 330, and the filter 400. It is discharged via, and each component is cleaned through the circulation of this inert gas.

The injection manifold set 300 is coupled with the foreway sampling valve 100 and the filter 400 for the line, and the chemical or inert gas injected through the foreway sampling valve 100 for the bypass line. Injected into the storage container 600, the gas in the storage container 600 is discharged to the external filter 400 side.

The injection manifold set 300 as shown in FIG. 5 illustrates the injection manifold set 300 of the injection manifold set of the real-time sampling apparatus including the four-way sampling valve for the bypass line of the present invention. ) Is composed of the manifold body 310, the sampling tube 320, the gas discharge pipe 330, pipe fixing part 340 and the sealing 350.

The manifold main body 310 is a line for sampling the injection manifold of the real-time sampling device including the four-way sampling valve for the bypass line of the present invention in detail, as shown in FIG. Coupled with the 100 has a sampling tube connecting hole 312 connecting the extraction hole 140 and the sampling tube 320.

In addition, the gas discharge pipe connecting hole 314 is coupled to the filter 400 and the gas discharge pipe 330 and the filter 400 is formed.

The sampling tube 320 is coupled to the manifold body 310 and connected to the sampling tube connecting hole 312 and inserted into the storage container 600 to inject a cleansing inert gas into the storage container 600. Inject the extracted chemical into the storage container 600.

The gas discharge pipe 330 is coupled to the manifold body 310 and connected to the gas discharge pipe connection hole 314 and inserted into the storage container 600 to filter the gas in the storage container 600. To the side.

As shown in FIG. 6, the sampling tube 320 and the gas discharge tube 330 are inserted into the sampling tube connection hole 312 and the gas discharge tube connection hole 314 of the manifold body 310. A groove 312-1 and a gas discharge pipe insertion groove 314-1 are formed, and the sampling pipe 320 and the gas discharge pipe 330 are inserted into the respective insertion grooves 312-1 and 314-1. Insertion heads 322 and 332 are formed.

That is, the coupling grooves 312-1 and 314-1 formed in the manifold body 310 and the insertion pipes 322 and 332 inserted therein are formed through the sampling pipe 320 and the gas discharge pipe 330. This facilitates, and prevents leakage of chemicals being extracted along with the sealing 350, and prevents leakage of toxic gas flowing out of the inert gas or chemical for cleaning.

The tube fixing unit 340 is made of a metal material, the through-hole is formed through the sampling tube 320 and the gas discharge pipe 330 is formed, and is coupled to the manifold body 310 and the fastening bolt 344 The sampling tube 320 and the gas discharge pipe 330 is fixed.

That is, the coupling between the manifold body 310 and the pipe fixing unit 340 is easy to replace the sampling pipe 320 and the gas discharge pipe 330 by screwing by the fastening bolt 344.

The seal 350 has a disc shape of a synthetic resin material as shown in FIGS. The sealing 350 prevents leakage of chemicals being extracted and prevents leakage of toxic gas flowing out of the inert gas or chemicals for cleaning.

In addition, the seal 350 further includes a Teflon seal 352. The Teflon sealing 352 is a sealing made of a high-performance fluorine resin Teflon (TEFLON) in the shape of a disc, and has characteristics such as heat resistance, chemical inertness, excellent electrical properties, and non-adhesiveness, which are not found in other general resins, Prevent spills.

The filter 400 is coupled to the injection manifold set 300, and is connected to the pipe as shown in FIG. The filter 400 filters the toxic substances while discharging the toxic gas in the storage container 600 generated during chemical extraction to the outside through the gas discharge pipe 330.

In this case, the filter 400 may be made of various materials, but preferably made of a carbon material having a high adsorption force on chemicals.

The storage container holder 500 is made of a metal material, as shown in FIGS. 4 and 5, coupled with the injection manifold set 300, and the storage container 600 is mounted.

The storage container holder 500 is inserted into the tube holder 340 of the injection manifold set 300 into the storage container holder 500 and coupled by fastening a screw from the side.

The storage container 600 is inserted into the storage container holder 500, the inlet is made of an elastic material is inserted through the sampling pipe 320 and the gas discharge pipe 330 of the injection manifold set 300. Such a storage container 600 may be a variety of storage containers used for sampling.

In the above, the present invention has been described based on the preferred embodiments, but the technical idea of the present invention is not limited thereto, and modifications or changes can be made within the scope of the claims. It will be apparent to those skilled in the art, and such modifications and variations will belong to the appended claims.

1: main line
2: sampling bypass line
3: T-branch
4: valve
5: Sampling unit
10: chemical
100: Four-way sampling valve for bypass line
110:
112: protruding coupling portion
120: bypass ball
130: branch hole
140: extraction hole
150: gas injection hole
160: branch hole opening and closing portion
162: plugging head
164: loading
166 handle
200: check valve
300: injection manifold set
310: manifold body
312: Sampling pipe connection
314: gas outlet pipe connection
320: sampling tube
330 gas discharge pipe
340: Official Government
344: fastening bolt
350: sealing
352: Teflon Shilling
400: filter
500: Storage Container Holder
600: storage container
700: gas line
710: Gas Distribution Control Valve

Claims (8)

In the sampling valve is installed in the sampling bypass line is coupled to the line through which the liquid chemical is passed in order to sample the liquid chemical produced in the chemical plant,
A main body made of a metal material and installed in the sampling bypass line;
A bypass hole formed through the main body and providing a flow path formed in parallel with the sampling bypass line so that chemicals for the purpose of extraction flowing through the sampling bypass line are circulated;
A branching hole formed in the main body and having one side communicating with the bypass hole and the other side communicating with the extraction hole;
The extraction hole communicates with the branch hole and the chemicals are introduced through the branch hole, or the inert gas for cleaning is introduced through the gas injection hole, and is in communication with the outside of the main body;
A gas injection hole communicating with the extraction hole and providing a gas flow path through which the inert gas injected for cleaning the extraction hole is injected into the extraction hole and communicating with the outside of the main body; And
And a branch hole opening and closing portion for opening and closing the branch hole across the extraction hole. The method of claim 1, wherein the body is
And a protrusion coupling portion extending from the body in a cylindrical shape at the position of the extraction hole and having a thread formed therein, wherein the extraction hole is continuous with the protrusion coupling portion and communicates with the outside of the body. Four-way sampling valve for bypass line. According to claim 1, The branch opening opening portion
A plugging head which is screwed into the main body to open and close a branch hole forward or backward and is inserted into the branch hole to open and close the branch hole; and a rod that is coupled to the plugging head and is screwed to the main body; and a handle for rotating the rod. Poway sampling valve for the bypass line, characterized in that consisting of. A bypass provided through the main body installed in the sampling bypass line and the main body and providing a flow path formed in parallel with the sampling bypass line so that chemicals for the purpose of extraction flowing through the sampling bypass line are distributed. It is formed in the ball and the main body and one side is in communication with the bypass hole and the other side is formed to communicate with the extraction hole and the branch hole is in communication with the chemical through the branch hole, or inert gas for cleaning through the gas injection hole And a gas injection hole communicating with the outside of the main body and a gas flow path communicating with the extraction hole so that the inert gas injected for cleaning the extraction hole is injected into the extraction hole and communicating with the outside of the main body. And opening and closing the branch hole across the extraction hole. Four-way sampling valve for the bypass line including a pore opening;
A check valve coupled to a gas injection hole of the foreway sampling valve for the bypass line to allow injection of a septic gas for cleaning;
Combined with the line four-way sampling valve and filter, injecting the chemical or inert gas injected through the by-line four-way sampling valve to the storage container, and discharges the gas in the storage container to the external filter side Injection manifold set;
A filter coupled to the injection manifold set and connected to the gas discharge pipe;
A storage container holder coupled to the injection manifold set and fixing the storage container inserted therein; And
And a storage container inserted into the storage container holder and having an inlet formed of an elastic material, into which the sampling pipe and the gas discharge pipe of the injection manifold set are inserted. Real time sampling device. The apparatus of claim 4, wherein the injection manifold set is
A manifold body comprising a sampling pipe connection hole coupled to the line four-way sampling valve to connect the extraction hole and the sampling tube, and a gas discharge pipe connection hole coupled to the filter to connect the gas discharge tube and the filter;
A sampling tube coupled to the manifold body and connected to the sampling tube connection hole and inserted into the storage container;
A gas discharge pipe coupled to the manifold body and connected to the gas discharge pipe connection hole and inserted into the storage container;
A pipe fixing part through which the sampling pipe and the gas discharge pipe penetrate and are coupled to the manifold body and the fastening bolt to fix the sampling pipe and the gas discharge pipe; And
Located between the manifold body and the pipe portion and the sealing to prevent leakage of chemicals and gases being extracted; Real-time sampling device including a foreway sampling valve for the bypass line. The method of claim 5, wherein the sealing
Real-time sampling device including a four-way sampling valve for the bypass line further comprises a Teflon sealing. The method of claim 5,
The sampling pipe connection hole and the gas discharge pipe connection hole of the manifold body are formed with a sampling pipe insertion groove and a gas discharge pipe insertion groove.
And a sampling head and a gas discharge pipe having insertion heads inserted into the respective insertion grooves. The method of claim 5, wherein the filter
Real-time sampling device, including a four-way sampling valve for the bypass line, characterized in that made of a carbon material.

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