KR102564937B1 - Carbon dioxxide detection device for total organic carbon analysis system and total organic carbon analysis system with this and manufacturing method of porous supporter - Google Patents

Abstract

The present invention is for a total organic carbon analysis system capable of uniformly dispersing carbon dioxide in a detection member, improving the detection performance of carbon dioxide, and minimizing a detection error when detecting carbon dioxide with a detection member in a total organic carbon analysis system. It relates to a carbon dioxide detection device, a total organic carbon analysis system equipped with the same, and a manufacturing method of a porous support.
To this end, the carbon dioxide detection device for the total organic carbon analysis system includes a barrel member through which oxidizing gas and carrier gas discharged from the sample oxidation module pass, a light source member for irradiating infrared rays into the barrel member, and infrared rays passing through the barrel member. A detection member for detecting the gas, an inlet diffusion member for diffusing and receiving the oxidizing gas and the carrier gas supplied through the inlet into which the oxidizing gas and carrier gas flow, and an inlet dispersion member equipped with an input dispersion hole for dispersing and transmitting the dispersion to the barrel member.

Description

Carbon dioxide detection device for total organic carbon analysis system, total organic carbon analysis system equipped with the same, and manufacturing method of porous support

The present invention relates to a carbon dioxide detection device for a total organic carbon analysis system, a total organic carbon analysis system equipped with the same, and a method for manufacturing a porous support, and more specifically, when detecting carbon dioxide as a detecting member in a total organic carbon analysis system, A carbon dioxide detection device for a total organic carbon analysis system capable of uniformly dispersing carbon dioxide in a detection member, improving the detection performance of carbon dioxide, and minimizing a detection error, a total organic carbon analysis system equipped with the same, and a method for manufacturing a porous support It is about.

Total organic carbon (TOC), chemical oxygen demand (COD), and biological oxygen demand (BOD) are all items that can determine water pollution by organic matter. Total organic carbon, chemical oxygen demand, and biochemical oxygen demand have different application items and standards because the test conditions and oxidation rates are different, respectively.

Here, total organic carbon is a method of quantifying organic carbon present in water by oxidizing it to carbon dioxide. Therefore, a general total organic carbon analyzer is largely measured through two steps. The first step is the process of oxidizing all the organic carbon in the sample to carbon dioxide, and the second step is the process of oxidizing the carbon dioxide produced by the oxidation of the organic carbon using conductivity or non-dispersive infrared (NDIR) spectroscopy, etc. It is the process of quantification using the method.

At this time, the process of oxidizing all the organic carbon in the sample to carbon dioxide can be applied using ultraviolet light and an oxidizing agent method, an oxidizing agent and heating method, a high-temperature combustion oxidation method, and a method using ultraviolet rays. Among these methods, the high-temperature combustion oxidation method is widely used because it has excellent oxidation efficiency and can analyze particulate samples and high-concentration organic wastewater. The high-temperature combustion oxidation method is cobalt oxide. It is a method of converting carbon in a sample into carbon dioxide by burning it in a high-temperature reactor of 550° C. or higher filled with an oxidizing catalyst such as platinum or barium chromate, and measuring it with a detector.

In addition, non-dispersive infrared spectroscopy measures the light absorption or light transmittance according to the concentration by using the property of carbon dioxide to absorb infrared rays of a specific wavelength, and when the oxidizing gas containing carbon dioxide passes through the lens barrel, Wavelength infrared rays are irradiated, and a non-dispersive infrared sensor detects the infrared rays.

However, in the conventional non-dispersive infrared spectroscopy, the oxidizing gas is supplied to the lens barrel together with the carrier gas. However, since the injection amount of the oxidizing gas supplied to the lens barrel is non-uniform, the amount of infrared detection detected by the detector varies greatly and a large detection error occurs. contains problems.

Republic of Korea Patent Registration No. 10-2176595 (2020. 11. 09. Announcement, title of invention: TOC measurement system using high frequency heating combustion)

An object of the present invention is to solve the conventional problems, and when detecting carbon dioxide with a detecting member in a total organic carbon analysis system, the carbon dioxide can be uniformly dispersed in the detecting member, and the detection performance of the carbon dioxide is improved and detected. It is an object of the present invention to provide a carbon dioxide detection device for a total organic carbon analysis system for minimizing an error, a total organic carbon analysis system equipped with the carbon dioxide detection device, and a method for manufacturing a porous support.

According to a preferred embodiment for achieving the above object of the present invention, a carbon dioxide detection device for a total organic carbon analysis system according to the present invention includes a barrel member through which an oxidizing gas and a carrier gas discharged from a sample oxidation module pass; a light source member for irradiating infrared rays into the barrel member; a detecting member for detecting infrared rays passing through the barrel member; an inlet diffusion member in which the oxidizing gas and the carrier gas supplied through an inlet through which the oxidizing gas and the carrier gas are introduced are diffused and accommodated; and an inlet dispersion member provided with an input dispersion hole for dividing the inlet diffusion member and the barrel member and dispersing the gas accommodated in the inlet diffusion member and delivering the gas to the barrel member.

Here, the infrared rays show a wavelength of 4.24 μm to 4.28 μm.

Here, the detecting member includes a non-dispersive infrared (NDIR) sensor.

Here, the diameter of the input distribution hole increases from a portion facing the inlet to an edge of the inlet distribution member.

Here, the inlet distributing member includes a single layer or two or more layers of porous support made of a poly tetra fluoro ethylene (PTFE) material.

A carbon dioxide detection device for a total organic carbon analysis system according to the present invention includes an outlet diffusion member accommodating the gas passing through the barrel member; an outlet distributing member disposed to face the inlet distributing member and provided with an exhaust distributing hole for dispersing the gas accommodated in the barrel member and passing it to an outlet through which the gas accommodated in the barrel member is discharged; And a module heat dissipation member for cooling the detection member; It further includes at least one of

Here, the diameter of the discharge distribution hole increases from a portion facing the outlet to an edge of the outlet distribution member.

Here, the outlet distributing member includes a single layer or two or more layers of porous support made of a poly tetra fluoro ethylene (PTFE) material.

Here, corresponding to the inlet dispersion member and the outlet dispersion member facing each other, the diameter of the input dispersion hole portion is greater than the diameter of the discharge dispersion hole portion.

Here, the module heat dissipation member may include one or more thermoelectric elements stacked and supported on the detecting member; and a heat dissipation fin part stacked on the thermoelectric element.

Here, the barrel member includes a first barrel part having the inlet dispersion member on one side and through which the oxidizing gas and the carrier gas pass; and a second barrel part provided on the other side of the first barrel part and through which the oxidizing gas and the carrier gas passing through the first barrel part pass, wherein the light source member emits infrared light into the first barrel part. a first light source unit that emits light; and a second light source unit for radiating infrared rays into the second barrel unit, wherein the detection member includes: a first detection unit for detecting infrared rays passing through the first barrel unit; and a second detection unit configured to detect infrared rays passing through the second barrel unit.

Here, an optical path of the infrared light in the first barrel part is equal to or shorter than an optical path of the infrared light in the second barrel part.

The carbon dioxide detection device for a total organic carbon analysis system according to the present invention divides the first barrel part and the second barrel part, and a barrel distribution hole through which gas accommodated in the first barrel part is dispersed and delivered to the second barrel part is formed through the barrel. A dispersing member; further includes.

Here, the diameter of the barrel dispersion hole increases from the central portion of the barrel dispersion member to the edge of the barrel dispersion member.

Here, the barrel dispersion member includes a single-layer or two- or more-layer porous support made of a poly tetra fluoro ethylene (PTFE) material.

Here, the diameter of the injection dispersion hole portion is larger than the diameter of the barrel dispersion hole portion corresponding to the inlet dispersion member and the barrel dispersion member facing each other.

An apparatus for detecting carbon dioxide for a total organic carbon analysis system according to the present invention includes a connection diffusion member through which gas accommodated in the first barrel part is diffused and accommodated; a first connection distribution member provided with a first connection distribution hole for partitioning the first barrel part and the connection diffusion member, and distributing the gas accommodated in the first barrel part and delivering the gas to the connection diffusion member; and a second connection distribution member having a second connection distribution hole that divides the connection diffusion member and the second barrel part, and distributes the gas accommodated in the connection diffusion member and delivers it to the second barrel part.

Here, the diameter of the first connection/distribution hole increases from the central portion of the first connection/distribution member to the edge of the first connection/distribution member.

Here, the diameter of the second connection/distribution hole increases from the central portion of the second connection/distribution member to the edge of the second connection/distribution member.

Here, at least one of the first connection-distribution member and the second connection-distribution member includes a single-layer or two- or more-layer porous support made of a poly tetra fluoro ethylene (PTFE) material.

Here, the diameter of the first connection/distribution hole part corresponding to the first connection/distribution member and the second connection/distribution member facing each other is equal to or greater than the diameter of the second connection/distribution hole part. In addition, the diameter of the input distribution hole portion is greater than the diameter of the first connection distribution hole portion corresponding to the input dispersion member and the first connection dispersion member facing each other. In addition, the diameter of the second connection distribution hole portion is larger than the diameter of the discharge distribution hole portion corresponding to the second connection distribution member and the discharge distribution member facing each other.

The total organic carbon analysis system according to the present invention includes a multi-port valve; a syringe pump connected to the multi-port valve; a sample oxidation module that is connected to the multi-port valve and heats the sample delivered from the multi-port valve to generate an oxidizing gas containing carbon dioxide; a detection module connected to the sample oxidation module to detect carbon dioxide included in the oxidizing gas, and including the carbon dioxide detection device according to any one of claims 1 to 21; and a gas supply module supplying a carrier gas to at least one of the multi-port valve, the syringe pump, the sample oxidation module, and the detection module.

Here, the sample oxidation module may include: a sample oxidation tube part forming a path through which at least the sample passes among the sample and the carrier gas; a sample catalyst unit built into the sample oxidation tube unit; and a sample oxidation furnace for heating the sample oxidation tube to burn at least the sample among the sample and the carrier gas. In addition, the sample oxidation module further includes a sample injection selector for selecting whether or not to supply at least the sample among the sample and the carrier gas. In addition, the sample catalyst unit includes a platinum catalyst.

The total organic carbon analysis system according to the present invention includes a cooling module for cooling the oxidizing gas discharged from the sample oxidation module; a water separation module separating moisture from the oxidizing gas discharged from the sample oxidation module; a dehumidification module for drying the oxidizing gas discharged from the sample oxidation module; a scrubber removing halogen components from the oxidizing gas discharged from the sample oxidation module; a filter module filtering foreign matter particles from the oxidizing gas discharged from the sample oxidation module; It further includes at least one of

The method for manufacturing a porous support according to the present invention is a method for manufacturing a porous support included in a carbon dioxide detection device according to the present invention, and after mixing poly tetra fluoro ethylene (PTFE) resin and a lubricant, compression A preforming step of preparing a compressed product by doing; Extrusion step of producing an extrudate by extruding the compressed product; A rolling step of producing a rolled product by rolling the extrudate; and a stretching step of stretching the rolled product in at least one direction of a machine direction (MD) and a cross direction (CD).

Here, the stretching step may include: a first pore forming step of manufacturing a primary support body by gripping an edge of the rolled product and stretching it in at least one direction of a machine direction and a cross direction; and a second pore forming step of manufacturing a secondary support by fixing the central portion of the primary support and then gripping the edge of the primary support and stretching it in at least one of a machine direction and a cross direction. do.

According to the carbon dioxide detection device for the total organic carbon analysis system according to the present invention, the total organic carbon analysis system equipped with the same, and the manufacturing method of the porous support, when carbon dioxide is detected by the detection member in the total organic carbon analysis system, carbon dioxide is detected by the detection member. can be uniformly dispersed, the detection performance of carbon dioxide can be improved, and the detection error can be minimized.

In addition, according to the present invention, the oxidizing gas and the carrier gas introduced through the inlet through the inlet diffusion member can be diffused and received as a uniform mixture.

In addition, according to the present invention, the gas received in the inlet diffusion member can be uniformly delivered to the barrel member through the inlet dispersion member, and laminar flow of the gas received in the barrel member can be induced.

In addition, the present invention can improve the absorption rate of infrared rays in carbon dioxide included in the gas passing through the barrel member by limiting the wavelength of infrared rays.

In addition, the present invention can stably measure light absorbance or light transmittance through the non-dispersive infrared ray sensor through the limitation of the detection member.

In addition, the present invention can stably deliver the gas accommodated in the inlet diffusion member to the barrel member and induce laminar flow of gas in the barrel member by limiting the diameter of the input distribution hole.

In addition, according to the present invention, the input distribution hole is easily formed through the material of the inlet diffusion member, and the gas contained in the inlet diffusion member is stably transmitted.

In addition, the present invention can stably receive the gas transmitted from the barrel member through the outlet diffusion member, smoothly guide the gas to the outlet, and stably maintain the laminar flow of the gas accommodated in the barrel member.

In addition, according to the present invention, the gas contained in the barrel member can be stably transferred to the outlet diffusion member or the outlet unit through the outlet dispersion member, and the laminar flow of the gas contained in the barrel member can be stably maintained.

In addition, the present invention can stably discharge the gas accommodated in the barrel member and stably maintain the laminar flow of gas in the barrel member by limiting the diameter of the discharge distribution hole.

In addition, the present invention easily forms the discharge distribution hole through the material of the outlet distribution member, and allows the gas contained in the barrel member to pass stably.

In addition, the present invention can increase the time for the gas contained in the barrel member to stay in the barrel member and improve detection accuracy and measurement accuracy through the difference between the diameter of the input distribution hole and the discharge distribution hole.

In addition, the present invention can dissipate heat from the detection member through the module heat dissipation member and improve measurement accuracy in the detection member.

In addition, the present invention can improve the heat dissipation effect of the detection member through the detailed coupling relationship of the module heat dissipation member, prevent the occurrence of errors due to overheating of the detection member, and prevent the measurement accuracy from being lowered.

In addition, the present invention can increase the residence time of the gas accommodated in the barrel member and improve the measurement accuracy through the barrel member having a two-stage structure.

In addition, since the optical path of infrared light is limited in the first and second barrel parts, the measurement accuracy can be improved by clearly compensating for measurement errors and improving the absorption rate of infrared rays in carbon dioxide contained in the barrel member. .

In addition, the present invention allows the gas accommodated in the first barrel to be stably transferred to the second barrel through the barrel dispersion member, stably maintains the laminar flow of the gas accommodated in the first barrel, and the laminar flow of the gas accommodated in the second barrel. movement can be induced.

In addition, the present invention can stably discharge the gas contained in the first barrel and stably maintain the laminar flow of the gas in the first barrel by limiting the diameter of the barrel distribution hole.

In addition, according to the present invention, the barrel dispersion hole is easily formed through the material of the barrel dispersion member, and the gas contained in the first barrel is stably transmitted.

In addition, the present invention can increase the residence time of the gas accommodated in the first barrel and improve detection accuracy and measurement accuracy through the difference between the diameter of the input dispersion hole and the barrel dispersion hole.

In addition, the present invention can stably receive the gas transmitted from the first barrel through the connection diffusion member, smoothly guide the gas to the second barrel, and stably maintain the laminar flow of the gas accommodated in the first barrel. there is.

In addition, the present invention enables the gas contained in the first barrel part to be stably transferred to the connected diffusion member through the first connected dispersion member, and can stably maintain the laminar flow of the gas contained in the first barrel part.

In addition, the present invention allows the gas accommodated in the connected diffusion member to be uniformly delivered to the second barrel unit through the second connected dispersion member, and induces laminar flow of the gas accommodated in the second barrel unit.

In addition, the present invention can stably deliver the gas accommodated in the first barrel part to the connection diffusion member and stably maintain the laminar flow of gas in the first barrel part by limiting the diameter of the first connection distribution hole.

In addition, the present invention can stably deliver the gas accommodated in the connection diffusion member to the second barrel part and induce a laminar flow of gas in the second barrel part by limiting the diameter of the second connection distribution hole part.

In addition, the present invention can easily form at least one of the first connection and distribution hole part and the second connection and distribution hole part through at least one material of the first connection and distribution member and the second connection and distribution member, and stabilize the delivery of gas. can

In addition, the present invention increases the residence time of the gas accommodated in the connection diffusion member in the connection diffusion member through the difference in diameter of the first connection distribution hole part and the diameter of the second connection distribution hole part, and stabilizes the gas in the second barrel part. and laminar movement of stable gas can be induced in the second barrel.

In addition, the present invention can increase the residence time of the gas accommodated in the first barrel and improve the detection accuracy and measurement accuracy through the difference between the diameter of the input distribution hole and the first connection distribution hole.

In addition, the present invention increases the residence time of the gas accommodated in the second barrel and improves detection accuracy and measurement accuracy through the difference between the diameter of the second connection and distribution hole and the discharge distribution hole.

In addition, the present invention can clarify the generation of carbon dioxide in response to the sample through the total organic carbon analysis system, enable the detection module to clearly detect carbon dioxide, and improve measurement accuracy.

In addition, the present invention can stably heat the sample through the sample oxidation module and clearly generate carbon dioxide according to the combustion of the sample.

In addition, the present invention conveniently removes at least one of moisture, halogen components, and foreign matter particles included in the oxidizing gas generated in the sample oxidation module through the interference removal module, improves the purity of the oxidizing gas delivered to the detection module, Measurement accuracy can be improved in the detection module.

In addition, the present invention can cool the oxidizing gas by including a cooling module as a detailed configuration of the interference removal module, prevent the detection module from deteriorating the ability to measure carbon dioxide due to heat, and clearly measure carbon dioxide in the detection module. let it do

In addition, the present invention can remove moisture from the oxidizing gas by including the brackish water separation module as a detailed configuration of the interference removal module, prevent the detection module from deteriorating the ability to measure carbon dioxide due to moisture, and prevent the detection module from deteriorating the carbon dioxide should be clearly measured.

In addition, the present invention includes a dehumidification module as a detailed configuration of the interference removal module, so that moisture can be removed from the oxidizing gas, preventing the detection module from deteriorating the ability to measure carbon dioxide due to moisture, and removing carbon dioxide from the detection module. to be clearly measured.

In addition, the present invention includes a scrubber as a detailed configuration of the interference removal module, so that halogen components can be removed from the oxidizing gas, preventing the detection module from deteriorating the ability to measure carbon dioxide due to the halogen components, and carbon dioxide in the detection module. should be clearly measured.

In addition, the present invention includes a filter module as a detailed configuration of the interference removal module, so that foreign matter particles included in the oxidizing gas can be removed, and the detection module prevents the detection module from deteriorating the ability to measure carbon dioxide due to the foreign matter particles. Make sure that the module measures carbon dioxide clearly.

In addition, the present invention makes it possible to conveniently manufacture the dispersion member applied to the present invention through the manufacturing method of the porous support, and to stably form the dispersion hole portion in the dispersion member.

1 is a diagram showing a total organic carbon analysis system according to an embodiment of the present invention.
2 is a diagram showing a first example of a detection module in a total organic carbon analysis system according to an embodiment of the present invention.
3 is a diagram showing a second example of a detection module in the total organic carbon analysis system according to an embodiment of the present invention.
4 is a diagram illustrating a method of manufacturing a porous support applied to a detection module in a total organic carbon analysis system according to an embodiment of the present invention.

Hereinafter, an embodiment of a carbon dioxide detection device according to the present invention, a total organic carbon analysis system equipped therewith, and a method for manufacturing a porous support will be described with reference to the accompanying drawings. At this time, the present invention is not limited or limited by the examples. In addition, in describing the present invention, detailed descriptions of well-known functions or configurations may be omitted to clarify the gist of the present invention.

A total organic carbon analysis system according to an embodiment of the present invention will now be described with reference to FIGS. 1 to 3 . At this time, the carbon dioxide detection device for the total organic carbon analysis system according to an embodiment of the present invention will be described as being included in the total organic carbon analysis system according to an embodiment of the present invention.

A total organic carbon analysis system according to an embodiment of the present invention includes a multi-port valve 20, a syringe pump 30 connected to the multi-port valve 20, and a multi-port valve connected to the multi-port valve 20. A sample oxidizing module 40 that heats the sample delivered from 20 to generate an oxidizing gas containing carbon dioxide, and a detection module 50 that is connected to the sample oxidizing module 40 and detects carbon dioxide included in the oxidizing gas and a gas supply module 60 for supplying a carrier gas to at least one of the multi-port valve 20, the syringe pump 30, the sample oxidation module 40, and the detection module 50.

The multiport valve 20 is provided with one common port and a plurality of distribution ports. A gas supply module 60 may be connected to one of the plurality of distribution ports to provide carrier gas to the multi-port valve 20 .

The syringe pump 30 is connected to the common port. The syringe pump 30 may be operated according to the supply of the carrier gas.

The sample oxidation module 40 is connected to a first port among a plurality of distribution ports. The sample oxidation module 40 provides an oxidizing gas by burning the carrier gas and the sample supplied through the first port. The sample oxidation module 40 may burn the sample by a high-temperature combustion oxidation method.

The sample oxidation module 40 includes a sample oxidation tube part 42 forming a path through which at least a sample passes among the sample and carrier gas, a sample catalyst part 43 built in the sample oxidation tube part 42, and the sample and carrier gas. Among them, at least a sample oxidation furnace unit 41 for heating the sample oxidation tube unit 42 for combustion of the sample may be included. The sample oxidation module 40 may further include a sample injection selector 44 that selects whether or not to supply at least one of the sample and the carrier gas. A platinum catalyst may be included in the sample catalyst unit 43 .

Since the heating temperature of the sample oxidation furnace 41 ranges from 650° C. to 900° C., complete oxidation of the organic carbon of the sample can be realized. At this time, when the heating temperature is lower than 650 ° C, organic carbon may be discharged as it is due to incomplete combustion of organic carbon, and when the heating temperature is higher than 900 ° C, overheating or damage of the sample oxidation module 40, sample catalyst unit ( 43) may be lost.

Looking at the operation of the sample oxidation module 40, when the sample injection selection unit 44 is operated as “on”, at least a sample among the sample and the carrier gas is supplied to the sample oxidation tube unit 42. At this time, since the sample oxidation furnace unit 41 heats the sample oxidation tube unit 42, the sample and the carrier gas are burned, and carbon dioxide is generated while organic carbon included in the sample is burned. Then, as the sample is completely burned, organic carbon is removed and carbon dioxide is generated in response thereto, so the sample oxidation module 40 removes organic carbon from the mixture of the sample and the carrier gas and provides an oxidizing gas containing carbon dioxide. . The oxidizing gas is delivered to the blockage removal module 90 or detection module 50. Here, a carrier gas may be supplied to smoothly transfer the oxidizing gas.

When the sample injection selector 44 is operated as “off”, the supply of the sample is cut off, and the sample remaining in the sample injection selector 44 may be discharged into the atmosphere or collected separately.

Although the sample oxidation module 40 has been described as applying a high-temperature combustion oxidation method, it is not limited thereto, and various known oxidation methods may be applied to oxidize a sample to generate carbon dioxide.

The detection module 50 may include a carbon dioxide detection device for a total organic carbon analysis system according to an embodiment of the present invention.

A carbon dioxide detection device for a total organic carbon analysis system according to an embodiment of the present invention includes a barrel member 51 through which at least one of an oxidizing gas and a carrier gas discharged from a sample oxidation module 40 passes, and a barrel member 51 ) may include a light source member 52a for irradiating infrared rays and a detection member 52b for detecting infrared rays passing through the barrel member 51.

In particular, the carbon dioxide detection device for the total organic carbon analysis system according to an embodiment of the present invention includes an inlet diffusion member in which the oxidizing gas and the carrier gas supplied through the inlet 501 into which the oxidizing gas and the carrier gas are introduced are diffused and accommodated ( 53), the inlet diffusion member 53 and the barrel member 51 are divided, but the inlet dispersion member provided with an input dispersion hole for dispersing the gas accommodated in the inlet diffusion member 53 and delivering it to the barrel member 51 ( 54) may be further included.

The gas passed through the barrel member 51 and discharged to the outlet may be discharged to the atmosphere as it is or passed through the adsorption module 80 and then discharged to the atmosphere.

The barrel member 51 has a hollow cylindrical shape. One side of the barrel member 51 is opened so that at least one of the oxidizing gas and the carrier gas discharged from the sample oxidation module 40 passes, and the other side of the barrel member 51 is open so that the gas received in the barrel member 51 passes. to be discharged. A light source member 52a is provided at one end of the barrel member 51 between both sides of the barrel member 51 that has been opened, and a light source member 52a is provided at the other end of the barrel member 51 between both sides of the barrel member 51 that has been opened. A detecting member 52b may be provided to face the member 52a.

The light source member 52a emits infrared rays, and infrared rays emitted from the light source member 52a may have a wavelength of 4.24 μm to 4.28 μm.

The detecting member 52b may be of a single type or of a dual type.

The detecting member 52b may include a non-dispersive infrared (NDIR) sensor.

An inlet part 501 connected to the sample oxidation module 40 or the interference removal module 90 is connected to one side of the inlet diffusion member 53, and the inlet dispersion member 54 is connected to the other side of the inlet diffusion member 53. are provided

The inlet diffusion member 53 has a funnel shape in which a space expands from one side to the other side, so that the oxidizing gas and the carrier gas can be diffused and accommodated.

The inlet diffusion member 54 disperses the gas accommodated in the inlet diffusion member 53 and delivers it to the barrel member 51 . At this time, since the diameter of the input dispersion hole increases from the portion facing the inlet portion 501 to the edge of the inlet dispersion member 54, the diffused gas can be stably dispersed according to the shape of the inlet diffusion member 53. there is.

The inlet dispersion member 54 may include a single layer or two or more layers of porous support made of a poly tetra fluoro ethylene (PTFE) material. Here, the porous support may be prepared by a method for manufacturing a porous support according to an embodiment of the present invention.

In the carbon dioxide detection device for a total organic carbon analysis system according to an embodiment of the present invention, an outlet diffusion member 58 in which gas passing through a barrel member 51 is accommodated and an inlet dispersion member 54 are disposed to face each other, and the barrel member 51 is disposed to face the barrel. Cools the outlet distributing member 59 equipped with a discharge distributing hole for dispersing the gas accommodated in the member 51 and passing it to the outlet unit 502 from which the gas accommodated in the barrel member 51 is discharged, and the detection member 52b. At least one of the module heat dissipation member 52c may be further included.

One side of the outlet diffusion member 58 is connected to the other side of the barrel member 51 or the outlet dispersion member 59, and the outlet unit 502 is connected to the other side of the outlet diffusion member 58.

As the out-diffusion member has a funnel shape in which a space is reduced from one side to the other side, the gas transmitted from the barrel member 51 can be collected and guided to the outlet part 502 .

The outlet dispersion member 59 disperses the gas accommodated in the barrel member 51 and delivers it to the outlet diffusion member 58 or the outlet unit 502 . At this time, the diameter of the discharge distribution hole increases from the portion facing the outlet part 502 to the edge of the outlet distribution member 59, so that the gas accommodated in the barrel member 51 is released according to the shape of the outlet diffusion member 58. It can be stably delivered to the outlet diffusion member 58 or the outlet part 502.

The outlet distributing member 59 may include a single layer or two or more layers of porous support made of a poly tetra fluoro ethylene (PTFE) material. Here, the porous support may be prepared by a method for manufacturing a porous support according to an embodiment of the present invention.

Corresponding to the inlet dispersion member 54 and the outlet dispersion member 59 facing each other, the diameter of the input dispersion hole is larger than the diameter of the discharge dispersion hole, so the residence time of the gas in the barrel member 51 can be extended. .

The module heat dissipation member 52c may include one or more thermoelectric elements 52c-1 stacked and supported on the detecting member 52b, and a heat dissipation fin part 52c-2 stacked on the thermoelectric element 52c-1. The cooling part of the thermoelectric element 52c-1 is in contact with or closely adhered to the detection member 52b, and the heating part of the thermoelectric element 52c-1 is brought into contact with or closely adhered to the radiating fin part 52c-2 to detect the detection member 52b. It is possible to improve the heat dissipation effect and prevent overheating of the detection member 52b.

A carbon dioxide detection device for a total organic carbon analysis system according to an embodiment of the present invention may have a dual structure as shown in FIG. 3 .

At this time, the barrel member 51 includes a first barrel part 511 provided with an inlet dispersion member 54 on one side and through which oxidizing gas and carrier gas pass, and a first barrel part 511 provided on the other side of the first barrel part 511 and the first barrel part ( 511) may include a second barrel part 512 through which the oxidizing gas and the carrier gas pass.

Then, the inlet dispersion member 54 is provided on one side of the first barrel part 511, and the barrel dispersion member or the first connection dispersion member 55 is provided on the other side of the first barrel part 511. In addition, a barrel dispersion member or a second connection dispersion member 57 is provided on one side of the second barrel unit 512, and at least one of an outlet diffusion unit or an outlet dispersion unit is provided on the other side of the second barrel unit 512. .

In addition, the light source member 52a includes a first light source unit 521a for irradiating infrared rays into the first barrel part 511 and a second light source unit 522a for irradiating infrared rays into the second barrel part 512. can do.

In addition, the detection member 52b includes a first detection unit 521b for detecting infrared rays passing through the first barrel part 511 and a second detection unit 522b for detecting infrared rays passing through the second barrel part 512. can do.

In addition, the module heat dissipation member 52c may include a first heat dissipation part 521c for cooling the first detection part 521b and a second heat dissipation part 522c for cooling the second detection part 522b.

Here, since the optical path of the infrared rays in the first barrel part 511 is formed equal to or shorter than the optical path of the infrared rays in the second barrel part 512, the information measured by the first detection unit 521b and the information measured by the second detection unit 522b It allows the measured information to be compared or analyzed.

For example, in the double structure as shown in FIG. 3, the carbon dioxide detection device for a total organic carbon analysis system according to an embodiment of the present invention partitions a first barrel part 511 and a second barrel part 512, A barrel dispersion member having a barrel dispersion hole through which the gas accommodated in the barrel unit 511 is dispersed and transmitted to the second barrel unit 512 may be further included.

First, the length of the inlet dispersion member 54 is substantially the same as that of the barrel dispersion member, corresponding to the length difference between the first barrel portion 511 and the second barrel portion 512, and the length of the outlet dispersion member 58 is Since it is formed longer than the length of the barrel dispersion member, the gas accommodated in the first barrel part 511 is transferred to the second barrel part 512 and stably diffused and dispersed to facilitate the laminar flow of gas in the second barrel part 512. can

Second, the length of the outlet dispersion member 58 is substantially the same as that of the barrel dispersion member, corresponding to the length difference between the first barrel portion 511 and the second barrel portion 512, and the length of the inlet dispersion member 54 is Since it is formed shorter than the length of the barrel dispersion member, the gas accommodated in the first barrel part 511 is transferred to the second barrel part 512 and stably diffused and dispersed to facilitate the laminar flow of gas in the second barrel part 512. can

Third, corresponding to the difference in length between the first barrel part 511 and the second barrel part 512, the length of the inlet dispersion member 54 is the shortest and the length of the outlet dispersion member 58 is the longest. Since the length is longer than the length of the inlet dispersion member 54 and shorter than the length of the outlet dispersion member 58, the gas contained in the first barrel part 511 is stably diffused and dispersed while being transferred to the second barrel part 512. The laminar flow of gas in the second barrel part 512 can be smoothly moved.

Fourth, the length of the inlet dispersion member 54, the length of the barrel dispersion member, and the length of the outlet dispersion member 58 are substantially the same in response to the difference in length between the first barrel portion 511 and the second barrel portion 512. Therefore, the gas accommodated in the first barrel part 511 is transferred to the second barrel part 512 and is stably diffused and dispersed, so that the laminar flow of the gas in the second barrel part 512 can be smoothly moved.

Since the diameter of the barrel dispersion hole increases from the central part of the barrel dispersion member to the edge of the barrel dispersion member, the first barrel part 511 ) can be stably transferred to the second barrel part 512 .

The barrel dispersion member may include a single layer or two or more layers of porous support made of a poly tetra fluoro ethylene (PTFE) material. Here, the porous support may be prepared by a method for manufacturing a porous support according to an embodiment of the present invention.

Corresponding to the inlet dispersion member 54 and the barrel dispersion member facing each other, the input dispersion hole has a larger diameter than the barrel dispersion hole, so the residence time of the gas in the first barrel portion 511 can be formed longer.

Corresponding to the barrel dispersion member and the outlet dispersion member 59 facing each other, the diameter of the barrel dispersion hole is greater than the diameter of the discharge dispersion hole, so the residence time of the gas in the second barrel portion 512 can be formed longer.

As another example, in the double structure as shown in FIG. 3, the carbon dioxide detection device for a total organic carbon analysis system according to an embodiment of the present invention includes a connection diffusion member 56 in which gas accommodated in the first barrel part 511 is diffused and received. And, while partitioning the first barrel part 511 and the connection diffusion member 56, the first connection distribution hole portion for dispersing and delivering the gas accommodated in the first barrel part 511 to the connection diffusion member 56 is provided. The second connection and distribution of dividing the connection dispersion member 55, the connection diffusion member 56, and the second barrel part 512, dispersing the gas accommodated in the connection diffusion member 56 and delivering it to the second barrel part 512. A second connection distributing member 57 having a hole may be further included.

A first connected dispersing member 55 is provided on one side of the connected diffusing member 56, and a second connected distributing member 57 is provided on the other side of the connected diffusing member 56.

As the connection diffusion member 56 has a funnel shape in which a space expands from one side to the other side, it can diffusely accommodate the gas transmitted from the first barrel part 511 .

Here, the length of the inlet dispersion member 54 is substantially the same as the length of the first connection dispersion member 55 corresponding to the difference in length between the first barrel part 511 and the second barrel part 512, and the length of the second connection dispersion member 55 is The length of the member 57 is substantially the same as the length of the outlet dispersing member 58, and the length of the first connected distributing member 55 is shorter than the length of the second connected distributing member 57. It is not limited thereto, and can be applied in various ways corresponding to the length comparison of the barrel dispersion member. At this time, it is natural that the shape of the connection diffusion member 56 is changed corresponding to the length of the first connection distribution member 55 and the length of the second connection distribution member 57 . Accordingly, the gas accommodated in the first barrel part 511 is transferred to the second barrel part 512 and is stably diffused and dispersed so that the laminar flow of the gas in the second barrel part 512 can be smoothly moved.

Since the diameter of the first connection/distribution hole portion increases from the center of the first connection/distribution member 55 to the edge of the first connection/distribution member 55, the first barrel part 511 according to the shape of the connection diffusion member 56 ) can be stably transferred to the connection diffusion member 56.

Since the diameter of the second connection/distribution hole increases from the center of the second connection/distribution member 57 to the edge of the second connection/distribution member 57, the diffused gas is stabilized according to the shape of the connection diffusion member 56. It is dispersed so that it is transmitted to the second barrel part 512.

At least one of the first connection-distribution member 55 and the second connection-distribution member 57 may include a single-layer or two- or more-layer porous support made of a poly tetra fluoro ethylene (PTFE) material. Here, the porous support may be prepared by a method for manufacturing a porous support according to an embodiment of the present invention.

Corresponding to the first connection distribution member 55 and the second connection distribution member 57 facing each other, the diameter of the first connection distribution hole is equal to or greater than the diameter of the second connection distribution hole, so the connection diffusion member 56 To stably receive the gas transmitted through the first barrel part 511.

Corresponding to the input distribution member and the first connection distribution member 55 facing each other, the diameter of the input distribution hole part is larger than the diameter of the first connection distribution hole part, so that the residence time of the gas in the first barrel part 511 can be formed long. can

Corresponding to the second connection distribution member 57 and the discharge distribution member facing each other, the diameter of the second connection distribution hole is larger than the diameter of the discharge distribution hole, so that the residence time of the gas in the second barrel part 512 can be formed long. can

The total organic carbon analysis system according to an embodiment of the present invention may further include an interference removal module 90 disposed between the sample oxidation module 40 and the detection module 50 and removing interference substances from oxidizing gas. there is. The interfering substances may include at least one of air temperature, moisture, halogen components, and foreign matter particles.

The interference removal module 90 includes a cooling module 91 for cooling the oxidizing gas discharged from the sample oxidation module 40 and a water separation module 92 for separating moisture from the oxidizing gas discharged from the sample oxidation module 40. And, a dehumidification module 93 for drying the oxidizing gas discharged from the sample oxidation module 40, a scrubber 94 for removing halogen components from the oxidizing gas discharged from the sample oxidation module 40, and a sample oxidation module ( 40) may include at least one of filter modules 95 for filtering foreign matter particles in the oxidizing gas discharged.

The total organic carbon analysis system according to an embodiment of the present invention includes an autosampler for storing a liquid used as a sample, a sample supply unit 11 for storing a sample for analysis, and a diluent for adjusting the concentration of the sample. At least one of the diluent supply unit 12 and the acid supply unit 13 storing the acidic solution injected into the sample according to the calibration method may be further included.

An autosampler (not shown) is connected to a second port among the plurality of distribution ports. The sample supply unit 11 is connected to a third port among the plurality of distribution ports. The diluent supply unit 12 is connected to a fourth port among the plurality of distribution ports. An acid supply unit 13 is connected to a fifth port among the plurality of distribution ports.

A total organic carbon analysis system according to an embodiment of the present invention includes a data processing module 70 for analyzing carbon dioxide measured by the detection module 50, and carbon dioxide in gas discharged through an outlet through the detection module 50. It may further include at least one of the adsorption modules 80 for removing the.

As the barrel member 51 has a double structure, the data processing module 70 includes a first processing unit 71 that processes the information measured by the first detection unit 521b and the information measured by the second detection unit 522b. Includes a second processing unit 72 that processes information, and a processing and analysis unit 73 that collects the processing information of the first processing unit 71 and the processing information of the second processing unit 72 to calculate the total organic carbon of the sample can do. Thereby, it becomes possible to clarify information processing and calculate total organic carbon of a sample more accurately.

The adsorption module 80 is connected to the outlet and passes through the detection module 50 to adsorb carbon dioxide from gas discharged through the outlet. Accordingly, carbon dioxide can be removed from the gas discharged through the outlet through the detection module 50, and air pollution caused by carbon dioxide can be prevented.

The operation of the total organic carbon analysis system according to an embodiment of the present invention can measure the total organic carbon of a sample by applying various well-known forms, and a detailed description thereof will be omitted.

From now on, a method for manufacturing a porous support according to an embodiment of the present invention will be described with reference to FIG. 4 . A method for manufacturing a porous support according to an embodiment of the present invention is a method for manufacturing the above-described porous support.

A method for manufacturing a porous support according to an embodiment of the present invention includes a preforming step (S1) of preparing a compressed product by mixing poly tetra fluoro ethylene (PTFE) resin and a lubricant, and then compressing the mixture. An extrusion step (S2) of producing an extrudate by extruding water, a rolling step (S3) of producing a rolled product by rolling the extrudate, and the machine direction (MD, machine direction) and cross direction (CD, A stretching step (S4) of stretching in at least one of cross directions may be included.

Here, the preforming step (S1) includes a mixing step (S11) of preparing a mixture by mixing poly tetra fluoro ethylene (PTFE) resin and a lubricant, and a compression step of compressing the mixture to produce a compressed product (S12) may be included.

In addition, the stretching step (S4) includes the first pore forming step (S41) of manufacturing a primary support body by gripping the edge of the rolled product and stretching it in at least one direction of the machine direction and the cross direction, and any one of the primary support body A second pore forming step (S42) of manufacturing a secondary support by holding the edge of the primary support and stretching it in at least one of the machine direction and the cross direction after fixing the part.

The method for manufacturing a porous support according to an embodiment of the present invention further includes a cutting step (S5) of manufacturing a cutting support by cutting a secondary support to a size corresponding to the distribution member based on any one part of the primary support. It includes, and may further include a processing step (S6) of processing the cutting support into the corresponding dispersion member.

Then, any one part of the primary support body corresponds to the part facing the inlet part 501 based on the inlet distributing member 54 .

According to the above-described carbon dioxide detection device for the total organic carbon analysis system, the total organic carbon analysis system equipped with the same, and the manufacturing method of the porous support, when carbon dioxide is detected by the detection member 52b in the total organic carbon analysis system, the detection member ( Carbon dioxide can be uniformly dispersed in 52b), carbon dioxide detection performance can be improved, and detection errors can be minimized.

In addition, through the inlet diffusion member 53, the oxidizing gas and the carrier gas introduced through the inlet unit 501 can be diffused and received as a uniform mixture.

In addition, the gas accommodated in the inlet diffusion member 53 is uniformly transmitted to the barrel member 51 through the inlet dispersion member 54, and laminar flow of the gas contained in the barrel member 51 can be induced.

In addition, absorption of infrared rays in carbon dioxide included in gas passing through the barrel member 51 may be improved by limiting the wavelength of infrared rays.

In addition, through the limitation of the detecting member 52b, it is possible to stably measure the light absorbance or light transmittance through the non-dispersive infrared ray sensor.

In addition, the gas accommodated in the inlet diffusion member 53 can be stably transferred to the barrel member 51 by limiting the diameter of the input dispersion hole, and laminar flow of gas can be induced in the barrel member 51 .

In addition, the input distribution hole is easily formed through the material of the inlet diffusion member 54, and the gas accommodated in the inlet diffusion member 53 is stably transmitted.

In addition, the gas transmitted from the barrel member 51 can be stably received through the outlet diffusion member 58, the gas can be smoothly guided to the outlet part 502, and the gas accommodated in the barrel member 51 can have a laminar flow. can be kept stable.

In addition, the gas accommodated in the barrel member 51 through the outlet dispersion member 59 is stably transferred to the outlet diffusion member 58 or the outlet part 502, and the laminar flow of the gas contained in the barrel member 51 is stably stabilized. can keep it.

In addition, the gas accommodated in the barrel member 51 can be stably discharged and the laminar flow of gas in the barrel member 51 can be stably maintained by limiting the diameter of the discharge distribution hole.

In addition, the discharge distribution hole is easily formed through the material of the outlet distribution member 59, and the gas accommodated in the barrel member 51 is stably transmitted.

In addition, the time during which the gas accommodated in the barrel member 51 stays in the barrel member 51 is increased through the difference between the diameter of the input distribution hole and the discharge distribution hole, and detection accuracy and measurement accuracy can be improved.

In addition, heat can be radiated from the detection member 52b through the module heat dissipation member 52c, and measurement accuracy can be improved in the detection member 52b.

In addition, it is possible to improve the heat dissipation effect of the detection member 52b through the detailed coupling relationship of the module heat dissipation member 52c, prevent errors due to overheating of the detection member 52b, and prevent the measurement accuracy from deteriorating. there is.

In addition, the residence time of the gas accommodated in the barrel member 51 can be increased through the barrel member 51 having a two-stage structure, and measurement accuracy can be improved.

In addition, since the optical path of infrared rays is limited in the first barrel part 511 and the second barrel part 512, compensation for measurement errors is made clear, and the absorption rate of infrared rays is improved in the carbon dioxide contained in the barrel member 51 for measurement. precision can be improved.

In addition, the gas accommodated in the first barrel part 511 is stably transferred to the second barrel part 512 through the barrel dispersion member, and the laminar flow of the gas accommodated in the first barrel part 511 is stably maintained, and the second barrel part The laminar movement of the gas contained in 512 can be induced.

In addition, the gas accommodated in the first barrel part 511 can be stably discharged and the laminar flow of gas in the first barrel part 511 can be stably maintained by limiting the diameter of the barrel distribution hole.

In addition, the barrel dispersion hole is easily formed through the material of the barrel dispersion member, and the gas contained in the first barrel portion 511 is stably transmitted.

In addition, the time during which the gas accommodated in the first barrel part 511 stays in the first barrel part 511 is increased through the difference between the diameter of the injection and distribution hole and the diameter of the barrel distribution hole, and detection accuracy and measurement accuracy can be improved. .

In addition, the gas transmitted from the first barrel part 511 can be stably received through the connection diffusion member 56, the gas can be smoothly guided to the second barrel part 512, and the gas received in the first barrel part 511 The laminar flow of gas can be stably maintained.

In addition, the gas accommodated in the first barrel part 511 is stably transferred to the connected diffusion member 56 through the first connection dispersion member 55, and the laminar flow of the gas accommodated in the first barrel part 511 is stably maintained. can make it

In addition, the gas accommodated in the connected diffusion member 56 is uniformly delivered to the second barrel part 512 through the second connected dispersion member 57, and laminar flow of the gas accommodated in the second barrel part 512 is induced. can do.

In addition, the gas accommodated in the first barrel part 511 can be stably transferred to the connection diffusion member 56 through the limitation of the diameter of the first connection distribution hole, and the laminar flow of the gas can be stably maintained in the first barrel part 511. there is.

In addition, the gas accommodated in the connection diffusion member 56 is stably transferred to the second barrel part 512 through the limitation of the diameter of the second connection distribution hole, and the laminar flow of the gas can be induced in the second barrel part 512.

In addition, at least one of the first connection and distribution hole part and the second connection and distribution hole part is easily formed through at least one material of the first connection and distribution member 55 and the second connection and distribution member 57, and the gas is transmitted. can stabilize.

In addition, the residence time of the gas accommodated in the connection diffusion member 56 is increased in the connection diffusion member 56 through the difference between the diameter of the first connection distribution hole part and the diameter of the second connection distribution hole part, and the second barrel part 512 ), and laminar flow of the stable gas can be induced in the second barrel part 512 .

In addition, the length of time the gas accommodated in the first barrel part 511 stays in the first barrel part 511 is increased through the difference between the diameter of the input distribution hole part and the diameter of the first connection distribution hole part, and the detection accuracy and measurement accuracy are improved. can

In addition, the residence time of the gas accommodated in the second barrel part 512 is increased in the second barrel part 512 through the difference between the diameter of the second connection distribution hole part and the discharge distribution hole part diameter, and the detection accuracy and measurement accuracy can be improved. can

In addition, the generation of carbon dioxide in response to the sample can be clarified through the total organic carbon analysis system, the detection module 50 can clearly detect carbon dioxide, and the measurement accuracy can be improved.

In addition, it is possible to stably heat the sample through the sample oxidation module 40 and clearly generate carbon dioxide according to the combustion of the sample.

In addition, at least one of moisture, halogen components, and foreign matter particles contained in the oxidizing gas generated in the sample oxidation module 40 is easily removed through the interference removal module 90, and the oxidizing gas transmitted to the detection module 50 It is possible to improve the purity of and improve the measurement accuracy in the detection module 50.

In addition, as the cooling module 91 is included as a detailed configuration of the interference removal module 90, the oxidizing gas can be cooled, preventing the detection module 50 from deteriorating the ability to measure carbon dioxide due to heat, and the detection module (50) to clearly measure carbon dioxide.

In addition, as the water separation module 92 is included as a detailed configuration of the interference removal module 90, it is possible to remove moisture from the oxidizing gas, and to prevent the detection module 50 from deteriorating the ability to measure carbon dioxide due to moisture. and clearly measure carbon dioxide in the detection module 50.

In addition, as the dehumidification module 93 is included as a detailed configuration of the interference removal module 90, moisture can be removed from the oxidizing gas, and the detection module 50 prevents the measurement of carbon dioxide due to moisture from deteriorating. , to clearly measure carbon dioxide in the detection module 50.

In addition, as the scrubber 94 is included as a detailed configuration of the interference removal module 90, it is possible to remove halogen components from the oxidizing gas, and prevent the detection module 50 from deteriorating the ability to measure carbon dioxide due to the halogen components. and clearly measure carbon dioxide in the detection module 50.

In addition, as the filter module 95 is included as a detailed configuration of the interference removal module 90, foreign matter particles included in the oxidizing gas can be removed, and the ability of the detection module 50 to measure carbon dioxide caused by the foreign matter particles is reduced. and to clearly measure carbon dioxide in the detection module 50.

In addition, the dispersion member applied to the present invention is conveniently manufactured through the method of manufacturing the porous support, and the dispersion hole is stably formed in the dispersion member.

As described above, the preferred embodiments of the present invention have been described with reference to the drawings, but those skilled in the art can make various modifications to the present invention within the scope not departing from the spirit and scope of the present invention described in the claims below. may be modified or changed.

11: sample supply unit 12: diluent supply unit 13: acid supply unit
20: multiport valve 30: syringe pump 40: sample oxidation module
41: sample oxidation furnace unit 42: sample oxidation tube unit 43: sample catalyst unit
44: sample injection selection unit 50: detection module 501: inlet unit
502: outlet part 51: barrel member 52a: light source member
52b: detection member 52c: module heat dissipation member 52c-1: thermoelectric element
52c-2: radiation fin part 53: inlet diffusion member 54: inlet dispersion member
55: first connection dispersion member 56: connection diffusion member 57: second connection dispersion member
58: outlet diffusion member 59: outlet dispersion member 511: first barrel part
512: second barrel part 521a: first light source part 522a: second light source part
521b: first detection unit 522b: second detection unit 521c: first heat dissipation unit
522c: second heat dissipation unit
60: gas supply module 70: data processing module 71: first processing unit
72: second processing unit 73: processing analysis unit 80: adsorption module
90: obstruction removal module 91: cooling module 92: air separation module
93: dehumidification module 94: scrubber 95: filter module
S1: preforming step S11: mixing step S12: compression step
S2: extrusion step S3: rolling step S4: stretching step
S41: first pore formation step S42: second pore formation step S5: cutting step
S6: processing step

Claims (25)

a barrel member through which oxidizing gas and carrier gas discharged from the sample oxidation module pass;
a light source member for irradiating infrared rays into the barrel member;
a detecting member for detecting infrared rays passing through the barrel member;
an inlet diffusion member in which the oxidizing gas and the carrier gas supplied through an inlet through which the oxidizing gas and the carrier gas are introduced are diffused and accommodated; and
An inlet dispersion member provided with an input dispersion hole for dividing the inlet diffusion member and the barrel member, and dispersing the gas accommodated in the inlet diffusion member and delivering the gas to the barrel member;
The barrel member,
a first barrel part having the inlet dispersion member on one side and through which the oxidizing gas and the carrier gas pass; and
A second barrel part provided on the other side of the first barrel part and through which the oxidizing gas and the carrier gas passing through the first barrel part pass;
The light source member,
a first light source unit for irradiating infrared rays into the first barrel unit; and
A second light source unit for irradiating infrared rays into the second barrel unit; includes,
The detecting member,
a first detector for detecting infrared rays passing through the first barrel; and
A carbon dioxide detection device for a total organic carbon analysis system comprising a; second detection unit for detecting infrared rays passing through the second barrel unit.
According to claim 1,
The optical path of the infrared rays in the first barrel unit,
Carbon dioxide detection device for a total organic carbon analysis system, characterized in that the optical path of the infrared ray in the second barrel part is equal to or shorter.
According to claim 1,
and a barrel dispersion member dividing the first barrel part and the second barrel part, and having a barrel distribution hole formed therethrough to disperse gas accommodated in the first barrel part and deliver the gas to the second barrel part. Carbon dioxide detection device for analysis system.
According to claim 3,
The diameter of the barrel dispersion hole is
The carbon dioxide detection device for a total organic carbon analysis system, characterized in that it increases from the central portion of the barrel dispersion member to the edge of the barrel dispersion member.
According to claim 3,
In the barrel dispersion member,
A carbon dioxide detection device for a total organic carbon analysis system, characterized in that a single-layer or two-layer or more porous support made of a polytetrafluoroethylene (PTFE) material is included.
According to claim 3,
Corresponding to the inlet dispersion member and the barrel dispersion member facing each other, a diameter of the input dispersion hole is larger than a diameter of the barrel dispersion hole.
According to claim 1,
a connection diffusion member through which the gas accommodated in the first barrel part is diffused;
a first connection distribution member provided with a first connection distribution hole for partitioning the first barrel part and the connection diffusion member, and distributing the gas accommodated in the first barrel part and delivering the gas to the connection diffusion member; and
and a second connection distribution member provided with a second connection distribution hole for partitioning the connection diffusion member and the second barrel, and dispersing the gas accommodated in the connection diffusion member and delivering it to the second barrel. A carbon dioxide detection device for a total organic carbon analysis system.
According to claim 7,
The diameter of the first connection distribution hole is
The carbon dioxide detection device for a total organic carbon analysis system, characterized in that the carbon dioxide detection device for a total organic carbon analysis system, characterized in that the increase from the central portion of the first connected dispersion member to the edge of the first connected dispersion member.
According to claim 7,
The diameter of the second connection distribution hole,
The carbon dioxide detection device for a total organic carbon analysis system, characterized in that the carbon dioxide detection device for a total organic carbon analysis system, characterized in that the increase from the central portion of the second connected dispersion member to the edge of the second connected dispersion member.
According to claim 7,
At least one of the first connection distribution member and the second connection distribution member,
A carbon dioxide detection device for a total organic carbon analysis system, characterized in that a single-layer or two-layer or more porous support made of a polytetrafluoroethylene (PTFE) material is included.
According to claim 7,
Corresponding to the first connection distribution member and the second connection distribution member facing each other, the diameter of the first connection distribution hole part is equal to or greater than the diameter of the second connection distribution hole part for a total organic carbon analysis system, characterized in that carbon dioxide detector.
a barrel member through which oxidizing gas and carrier gas discharged from the sample oxidation module pass;
a light source member for irradiating infrared rays into the barrel member;
a detecting member for detecting infrared rays passing through the barrel member;
an inlet diffusion member in which the oxidizing gas and the carrier gas supplied through an inlet through which the oxidizing gas and the carrier gas are introduced are diffused and accommodated; and
An inlet dispersion member provided with an input dispersion hole for dividing the inlet diffusion member and the barrel member, and dispersing the gas accommodated in the inlet diffusion member and delivering the gas to the barrel member;
an outlet diffusion member accommodating the gas passing through the barrel member;
an outlet distributing member disposed to face the inlet distributing member and provided with an exhaust distributing hole for dispersing the gas accommodated in the barrel member and passing it to an outlet through which the gas accommodated in the barrel member is discharged; and
a module heat dissipation member cooling the detecting member; A carbon dioxide detection device for a total organic carbon analysis system, characterized in that it further comprises at least one of.
According to claim 12,
The diameter of the discharge distribution hole is,
Carbon dioxide detection device for a total organic carbon analysis system, characterized in that the increase in the portion facing the outlet portion toward the edge of the outlet distributing member.
According to claim 12,
In the outlet distribution member,
A carbon dioxide detection device for a total organic carbon analysis system, characterized in that a single-layer or two-layer or more porous support made of a polytetrafluoroethylene (PTFE) material is included.
According to claim 12,
Corresponding to the inlet dispersion member and the outlet dispersion member facing each other, the diameter of the input dispersion hole is larger than the diameter of the discharge dispersion hole.
According to claim 12,
The module heat dissipation member,
At least one thermoelectric element stacked and supported by the detection member; and
A carbon dioxide detection device for a total organic carbon analysis system comprising a; heat dissipation fin part laminated on the thermoelectric element.
a barrel member through which oxidizing gas and carrier gas discharged from the sample oxidation module pass;
a light source member for irradiating infrared rays into the barrel member;
a detecting member for detecting infrared rays passing through the barrel member;
an inlet diffusion member in which the oxidizing gas and the carrier gas supplied through an inlet through which the oxidizing gas and the carrier gas are introduced are diffused and accommodated; and
An inlet dispersion member provided with an input dispersion hole for dividing the inlet diffusion member and the barrel member, and dispersing the gas accommodated in the inlet diffusion member and delivering the gas to the barrel member;
The diameter of the input distribution hole is
The carbon dioxide detection device for a total organic carbon analysis system, characterized in that the increase in size from the portion facing the inlet to the edge of the inlet distributing member.
a barrel member through which oxidizing gas and carrier gas discharged from the sample oxidation module pass;
a light source member for irradiating infrared rays into the barrel member;
a detecting member for detecting infrared rays passing through the barrel member;
an inlet diffusion member in which the oxidizing gas and the carrier gas supplied through an inlet through which the oxidizing gas and the carrier gas are introduced are diffused and accommodated; and
An inlet dispersion member provided with an input dispersion hole for dividing the inlet diffusion member and the barrel member, and dispersing the gas accommodated in the inlet diffusion member and delivering the gas to the barrel member;
In the inlet dispersion member,
A carbon dioxide detection device for a total organic carbon analysis system, characterized in that a single-layer or two-layer or more porous support made of a polytetrafluoroethylene (PTFE) material is included.
According to any one of claims 1 to 18,
the infrared rays,
A carbon dioxide detection device for a total organic carbon analysis system, characterized in that it exhibits a wavelength of 4.24 μm to 4.28 μm.
According to any one of claims 1 to 18,
In the detecting member,
A carbon dioxide detection device for a total organic carbon analysis system, characterized in that a non-dispersive infrared (NDIR) sensor is included.
A method for producing the porous support according to any one of claims 5, 10, 14, and 18,
A preforming step of preparing a compressed product by mixing poly tetra fluoro ethylene (PTFE) resin and a lubricant and then compressing the mixture;
Extrusion step of producing an extrudate by extruding the compressed product;
A rolling step of producing a rolled product by rolling the extrudate; and
A stretching step of stretching the rolled product in at least one direction of a machine direction (MD) and a cross direction (CD),
In the stretching step,
A first pore forming step of manufacturing a primary support by gripping an edge of the rolled product and stretching it in at least one of a machine direction and a cross direction; and
A second pore forming step of manufacturing a secondary support by fixing the central portion of the primary support and then gripping the edge of the primary support and stretching it in at least one direction of the machine direction and the cross direction; Method for producing a porous support, characterized in that.
multiport valve;
a syringe pump connected to the multi-port valve;
a sample oxidation module that is connected to the multi-port valve and heats the sample delivered from the multi-port valve to generate an oxidizing gas containing carbon dioxide;
a detection module connected to the sample oxidation module to detect carbon dioxide included in the oxidizing gas, and including the carbon dioxide detection device according to any one of claims 1 to 18; and
and a gas supply module supplying a carrier gas to at least one of the multi-port valve, the syringe pump, the sample oxidation module, and the detection module.
The method of claim 22,
The sample oxidation module,
a sample oxidation tube part forming a path through which at least the sample passes among the sample and the carrier gas;
a sample catalyst unit built into the sample oxidation tube unit; and
and a sample oxidation furnace for heating the sample oxidation tube for combustion of at least the sample among the sample and the carrier gas.
The method of claim 22,
a cooling module cooling the oxidizing gas discharged from the sample oxidation module;
a water separation module separating moisture from the oxidizing gas discharged from the sample oxidation module;
a dehumidification module for drying the oxidizing gas discharged from the sample oxidation module;
a scrubber removing halogen components from the oxidizing gas discharged from the sample oxidation module;
a filter module filtering foreign matter particles from the oxidizing gas discharged from the sample oxidation module;
Total organic carbon analysis system, characterized in that it further comprises at least one of.
delete

Images