KR20200080710A - Analysis apparatus for total organic carbon 0f non-catalyst type - Google Patents

Abstract

The present invention relates to catalyst-free total organic carbon analysis device. More specifically, the present invention relates to a catalyst-free total organic carbon analysis device. The present invention allows high temperatures to be evenly distributed without using a catalyst, so that vaporization is sufficiently performed and salt does not condense inside. While analysis water is heated, the analysis water can be sprayed evenly to a ceramic ball inside a protection tube, thereby making maintenance of a high temperature state easy while an efficient analysis of total organic carbon can be efficiently performed.

Description

ANALYSIS APPARATUS FOR TOTAL ORGANIC CARBON 0F NON-CATALYST TYPE}

The present invention relates to a non-catalytic total organic carbon analyzer, and more specifically, to allow high temperature to be evenly distributed without using a catalyst, so that vaporization is sufficiently performed and salt is not condensed inside. Non-catalytic total organic carbon analysis to ensure that the high temperature state is facilitated by allowing the water to be evenly sprayed onto the ceramic balls in the protection tube while heated, and that the analysis of total organic carbon can be efficiently performed. It is about the device.

TOC (Total Organic Carbon) refers to the amount of carbon contained in the organic matter contained in water, along with the biochemical oxygen demand (BOD) and chemical oxygen demand (COD). It is used as a representative organic material indicator.

The method of analysis of total organic carbon (hereinafter referred to as TOC) is a process of removing inorganic carbon such as carbonate ions contained in a sample, a process of oxidizing an organic material into carbon dioxide using an oxidation reactor, and oxidized samples. It consists of an analysis process.

As a method of removing the inorganic carbon, it is common to remove the free inorganic carbon by adding acid to the sample to lower the pH and then bubbling with gas.

The oxidation method is largely divided into a wet oxidation method and a combustion oxidation method. The wet oxidation method is basically a method of oxidizing organic substances by irradiating ultraviolet rays to a sample. In order to increase the oxidizing power, a means of adding persulfate, increasing temperature, or introducing ozone may be used as an auxiliary. Combustion oxidation is a method of oxidizing organic substances at medium and high temperatures of 650 to 950℃. In the case of wet oxidation, it is suitable for analysis of samples with low concentration or low suspended solids, and for combustion oxidation, it is suitable for analysis of samples with high concentration or suspended solids.

As a method of analyzing the oxidized sample, a method of quantifying carbon dioxide generated in the oxidation process with a non-dispersive infrared sensor (NDIR sensor) and a method of measuring and comparing the electrical conductivity of the sample before and after oxidation are used. The method of measuring the electrical conductivity is suitable for the analysis of ultra-low concentration samples, and a non-dispersive infrared sensor is generally used.

The most important factor for the accurate and reproducible analysis of total organic carbon is the oxidation method that oxidizes organic substances to the maximum. Particularly, in the case of wet oxidation, since oxidation power is lower than combustion oxidation, various methods are used to increase the oxidation power.

As described above, a method that has been commonly used in the past is a method in which an oxidizing agent is added, a catalyst is charged into a reactor, or ozone is used, but it is difficult to accurately measure due to weak oxidizing power, and an analysis time is long and a process is complicated.

Republic of Korea Patent Registration No. 10-1307971 (2013.09.30.)'Measurement device for total organic carbon and total nitrogen content based on non-catalytic hot combustion oxidation method'

The present invention was devised to solve the above-mentioned problems, and the object of the present invention is to ensure that high temperature is evenly distributed without using a catalyst, so that vaporization is sufficiently performed and salt is not condensed inside, while the analyte water is heated. A non-catalytic total organic carbon analyzer is designed to ensure that the high temperature state can be easily maintained by allowing the ceramic balls in the protection tube to be evenly sprayed in the finished state, while at the same time efficiently analyzing the total organic carbon. Is to provide.

The problem to be solved of the present invention is not limited to those mentioned above, and other problems not mentioned will be clearly understood by those skilled in the art from the following description.

In order to achieve the above object, the present invention applies a method of converting the carbon component contained in the analysis water into carbon dioxide, a reactor having a cylindrical body and the lower portion of the body narrowing toward the bottom; A protection tube 22 inserted into the reactor 20; A ceramic ball 26 filled in the protection tube 22; A sieve 24 provided at a lower end of the protection tube 22 so as to be located at the bottom of the ceramic ball 26 and allowing a vaporized gas to escape as a plurality of through holes 240 are formed; And a heater 28 for adjusting the temperature in the protection tube 22 while wrapping the outer side of the reactor 20 in a coil form, in the non-catalytic total organic carbon analyzer, the ceramic ball 26 Further comprising an injection unit 100 to evenly spray the analysis water, the injection unit 100, the storage tank 110 to which the analysis water flows from the outside; A plurality of injection pipes 120 provided below the storage tank 110; And it is connected to each of the injection pipe 120, and provides a non-catalytic total organic carbon analysis apparatus characterized in that it comprises an injection nozzle 130 for spraying the analysis water to the ceramic ball (26).

The injection unit 100 according to the present invention further includes a pressing means 150 for pressing the analyzed water accommodated in the storage tank 110 to the injection pipe 120, wherein the pressing means 150 is the A guide bar 151 extending upward from an inner bottom surface of the storage tank 110; A floating body 152 coupled to the guide bar 151 so as to be elevated or lowered; And it characterized in that it comprises a weight 153 provided on the floating body 152.

The injection unit 100 according to the present invention further comprises a water level control means 160 for adjusting the water level of the analysis water received by the storage tank 110, the water level control means 160, from the outside Supply pipe 161 for supplying the analysis water to the storage tank 110; A control valve 162 provided in the supply pipe 161; An upper limit detection sensor 163 provided on an upper portion of the guide bar 151; A lower limit detection sensor 164 provided below the guide bar 151; And it characterized in that it comprises a control unit 165 for controlling the opening and closing of the control valve 162 according to the detection signal of the upper and lower limit detection sensors (163,164).

In addition, it is provided on the outside of the reactor 20, the housing 300 made of a heat insulating material; And a heat storage material 400 accommodated inside the housing 300, wherein the housing 300 has a groove 300a formed inward to form a'c' cross-section, and the heat storage material The 400 is made of a plurality of ceramic balls, and is accommodated in the groove portion 300a, it is characterized in that it is stored by the heat generated by the heater 28.

In the supply pipe 161 according to the present invention, one end is connected to the storage tank 110 and the analysis water is supplied from the outside to the other end, and the analysis water passing through the groove 300a between both ends passes through the heat storage. It is characterized by being heated by the ash 400 and accommodated in the storage tank 110.

According to the present invention, the temperature is uniformly distributed in the protection tube without using a catalyst, so that salt does not form crystals, and by promoting vaporization, measurement of total organic carbon can be smoothly maintained. There is an effect that can dramatically improve the problems caused by.

In addition, it is easy to maintain the high temperature state by being able to uniformly spray the ceramic ball in the protection tube while the analyte is heated, and also has an effect that the analysis of the total organic carbon can be efficiently performed.

The effects of the present invention are not limited to those mentioned above, and other problems not mentioned will be clearly understood by those skilled in the art from the following description.

1 is an exploded perspective view showing a non-catalytic total organic carbon analyzer according to the present invention.
FIG. 2 is a sectional view showing a state in which the reactor of FIG. 1 is assembled.
3 is a cross-sectional view showing another example of a ceramic ball in the non-catalytic total organic carbon analyzer according to the present invention.
Figure 4 is a cross-sectional view showing a state in which the injection unit is provided in the non-catalytic total organic carbon analyzer according to the present invention.
5 is a partially enlarged view showing the injection pipe in FIG. 4.
Figure 6 is a cross-sectional view showing a state equipped with a pressing means in the non-catalytic total organic carbon analyzer according to the present invention.
7 is a cross-sectional view showing a state in which the water level adjusting means is provided in FIG. 6.
And
8 is a cross-sectional view showing a state in which the housing and the heat storage material are provided in the non-catalytic total organic carbon analyzer according to the present invention.

Hereinafter, preferred embodiments of the present invention will be described in more detail with reference to the accompanying drawings.

1 to 2, the non-catalytic total organic carbon analyzer according to the present invention (hereinafter referred to as "total organic carbon analyzer") is a method for converting carbon components included in the analysis water into carbon dioxide As a total organic carbon analysis device to be applied, a reactor having a cylindrical body and a lower portion of the body having a tube shape narrowing toward the bottom is inserted into the reactor 20 and the sieve 24 at the bottom. The cylindrical protection tube 22 is installed, and the outside of the ceramic ball 26 and the reactor 20 filled in the protection tube 22 is wrapped in a coil form, and the temperature in the protection tube 22 is 1000 degrees to 1400 degrees. It includes a heater 28 to adjust and a temperature control unit (not shown) to supply current to the heater 28.

The sieve 24 is intended to allow the vaporized gas to escape while the ceramic ball 26 does not flow down and has a plurality of through holes 240 smaller than the diameter of the ceramic ball 26 to form a net structure. It is preferably made of a ceramic material.

The total organic carbon analysis apparatus according to the present invention is controlled to a temperature of 1000 to 1400 degrees and a ceramic ball is inserted into the protection tube, compared to the conventional catalyst method controlled to 600 to 1000 degrees, without using a catalyst such as platinum. The temperature is uniformly distributed in the protection tube so that salt does not form crystals and promotes vaporization so that TOC measurement is smoothly performed.

Referring to Figure 3, the total organic carbon analyzer according to the present invention is the first ceramic ball 460 on the bottom of the protection tube 22 has the largest particle size, the second ceramic ball 462 on the upper layer ) Has a smaller particle size than the first ceramic ball 460, and the third ceramic ball 464 on the upper layer has a smaller particle size than the second ceramic ball 462.

Next, the fourth ceramic ball 466 placed on the uppermost portion is smaller than the particle size of the third ceramic ball 464.

That is, as the particle size of the ceramic ball 26 increases from the bottom to the top, the first ceramic ball 460 at the bottom has the largest particle size, and the fourth ceramic ball 466 at the top has the smallest particle size. Is done.

The heat has the property of going up, and the particles become denser toward the top, resisting the property of the heat going up and reducing the heat from passing out of the tube to achieve the effect that the heat is evenly distributed in the tube. Can.

The TOC measuring apparatus according to the present invention as described above is capable of uniformly distributing a high temperature of about 1,200 degrees without using a catalyst, so that vaporization is sufficiently performed and salt does not condense inside, so it is very inexpensive in terms of maintenance and measurement data Is not much different from the existing catalyst method.

The apparatus for analyzing total organic carbon according to the present invention further includes an injection unit 100 for spraying the analysis water to the ceramic ball 26 as shown in FIG. 4.

The injection unit 100 allows the analysis water supplied from the outside to be sprayed evenly into the interior of the protection tube 22 so that the contact with the ceramic ball 26 can be smoothly made.

The injection unit 100 is connected to the storage tank 110, the plurality of injection pipes 120 provided at the lower portion of the storage tank 110, and each injection pipe 120 to which the analysis water flows from the outside. 26) includes an injection nozzle 130 to be injected.

The storage tank 110 is disposed on the upper part of the reactor 20, and the analysis water supplied from the outside is accommodated. Of course, a certain amount of analytical water for analysis may be accommodated in the storage tank 110.

The injection pipe 120 is branched so that the analysis water received in the reservoir 110 is evenly sprayed to the ceramic ball (26).

The injection pipe 120 has an upper portion connected to the lower portion of the storage tank 110 and a lower portion facing the ceramic ball 26, and is formed in a plurality to be radially disposed at the lower portion of the storage tank 110.

The injection nozzle 130 allows the analysis water passing through the injection tube 120 to be injected into the ceramic ball 26, and can achieve various known forms.

As the compressed air is supplied from the outside to the injection pipe 120, injection of the analysis water through the injection nozzle 130 may be smoothly performed.

5, the injection pipe 120 may be provided with an on-off valve 140.

The opening/closing valve 140 is opened or closed by the control of the control unit 165 so that the sprayed water is injected into the ceramic ball 26 or not.

Accordingly, the injection unit 100, the analysis water received by the storage tank 110 is branched through a plurality of injection pipes 120, while the spray is evenly sprayed through the injection nozzle 130, the analysis number and the ceramic ball 26 Even contact can be made.

The injection unit 100 further includes a pressing means 150 that pressurizes the analysis water received in the storage tank 110 to the injection pipe 120 as shown in FIG. 6.

The pressing means 150 is a guide bar 151 extending upward from the inner bottom surface of the storage tank 110, a floating body 152 and a floating body 152 coupled to the guide bar 151 so as to be elevated and lowered. ) Includes a weight 153 provided.

The guide bar 151 has a lower portion fixed to an inner bottom surface of the storage tank 110 and an upper portion passing through the floating body 152.

The floating body 152 is made of a material that can float on the analyzed water, and is moved up and down in the longitudinal direction of the guide bar 151 according to the change in the water level of the storage tank 110.

It is preferable that the weight body 153 is formed in a plate shape and is provided on the upper surface of the floating body 152.

The weight body 153 has a weight such that the floating body 152 can float on the analysis water, and pressurizes the analysis water received by the storage tank 110 to the injection pipe 120 to spray water from the storage tank 110. Induces smooth discharge.

The injection unit 100 further includes a water level control means 160 for adjusting the water level of the analysis water received in the storage tank 110 as shown in FIG. 7.

The water level control means 160 is a supply pipe 161 for supplying the analysis water from the outside to the storage tank 110, a control valve 162 provided in the supply pipe 161, an upper limit detection sensor provided on the upper portion of the guide bar 151 (163), a control unit 165 for controlling the opening and closing of the control valve 162 in accordance with the detection signal of the lower limit detection sensor 164 and the upper and lower limit detection sensors 163 and 164 provided on the lower portion of the guide bar 151 do.

The upper limit detection sensor 163 detects the upper limit water level of the storage tank 110 while coming into contact with the weight 153 according to the elevation of the floating body 152 according to the rise of the water level of the storage tank 110, and the lower limit detection sensor 164 Detects the lower limit water level of the storage tank 110 while coming into contact with the floating body 152 as the floating body 152 descends as the water level of the storage tank 110 falls.

The control unit 165 controls the control valve 162 to close according to the detection signal of the upper limit detection sensor 163, while controlling the control valve 162 to open according to the detection signal of the lower limit detection sensor 164.

Accordingly, the water level control means 160 may ensure that the water level of the storage tank 110 is properly maintained.

The apparatus for analyzing total organic carbon according to the present invention further includes a housing 200 provided on the outside of the reactor 20 and a heat storage material 300 accommodated inside the housing 200 as shown in FIG. 8.

The housing 200 is formed with a groove portion 200a inward, so that the longitudinal cross-section forms a'U' shape, and is preferably made of an insulating material.

The heat storage material 300 may be made of a plurality of ceramic balls and allow heat generated from the heater 28 to be stored while being accommodated in the groove portion 200a.

The supply pipe 161 is one end is connected to the storage tank 110 and the analysis water is supplied from the outside to the other end, it is most preferable that the two ends pass through the groove (200a).

This is to allow the analysis water supplied from the outside to be accommodated in the storage tank 110 while being heated by the heat storage material 300.

The supply pipe 161 may form a shape surrounding the outside of the heater 28 while forming a coil pipe shape between both ends.

For this reason, the total organic carbon analyzer according to the present invention can make the temperature change in the protection tube 22 minimum as compared to when the analyte in the non-heated state is injected into the ceramic ball 26, as well as the temperature. Energy consumption for maintenance can be greatly reduced.

In addition, as the temperature of the analyzed water rapidly becomes high temperature, analysis of total organic carbon can be performed more efficiently.

What has been described above is only an embodiment for implementing the non-catalytic total organic carbon analyzer according to the present invention, and the present invention is not limited to the above embodiment, as claimed in the following claims. Without departing from the gist of the present invention, any person having ordinary knowledge in the field to which the present invention pertains will have the technical spirit of the present invention to the extent that various changes can be implemented.

20: reactor 22: protection tube
24: sieve 26: ceramic ball
28: heater 100: injection unit
110: storage tank 120: spray pipe
130: injection nozzle 140: opening and closing valve
150: pressing means 151: guide bar
152: floating body 153: heavy body
160: water level control means 161: supply pipe
162: Control valve 163: Upper limit detection sensor
164: Lower limit detection sensor 165: Control unit
200: housing 300: heat storage material

Claims (5)

A method of converting carbon components contained in the analyzed water into carbon dioxide is applied.
A reactor 20 having a cylindrical body and the lower portion of the body narrowing toward the bottom;
A protection tube 22 inserted into the reactor 20;
A ceramic ball 26 filled in the protection tube 22;
A sieve 24 provided at a lower end of the protection tube 22 so as to be located at the bottom of the ceramic ball 26 and allowing a vaporized gas to escape as a plurality of through holes 240 are formed; And
In the non-catalytic total organic carbon analysis apparatus including a heater 28 for adjusting the temperature in the protection tube 22 while wrapping the outer side of the reactor 20 in a coil form,
The ceramic ball 26 further includes an injection unit 100 to spray the analysis water evenly,
The injection unit 100,
A storage tank 110 through which analysis water flows from the outside;
A plurality of injection pipes 120 provided below the storage tank 110; And
A non-catalytic total organic carbon analysis device, which is connected to the respective injection pipes (120) and includes an injection nozzle (130) for spraying the analysis water with a ceramic ball (26). According to claim 1,
The injection unit 100,
Further comprising a pressing means 150 for pressing the analysis water accommodated in the storage tank 110 to the injection pipe 120,
The pressing means 150,
A guide bar 151 extending upward from an inner bottom surface of the storage tank 110;
A floating body 152 coupled to the guide bar 151 so as to be elevated or lowered; And
A non-catalytic total organic carbon analysis device comprising a weight body (153) provided on the floating body (152). According to claim 2,
The injection unit 100,
Further comprising a water level control means 160 for adjusting the water level of the analysis water received in the storage tank 110,
The water level control means 160,
A supply pipe 161 for supplying analysis water from the outside to the storage tank 110;
A control valve 162 provided in the supply pipe 161;
An upper limit detection sensor 163 provided on an upper portion of the guide bar 151;
A lower limit detection sensor 164 provided below the guide bar 151; And
And a control unit (165) for controlling opening and closing of the control valve (162) according to the detection signals of the upper and lower limit detection sensors (163, 164). According to claim 3,
A housing 300 provided outside the reactor 20 and made of an insulating material; And
Further comprising a heat storage material 400 accommodated in the interior of the housing 300,
The housing 300,
As the groove portion 300a is formed inward, the longitudinal section forms a'c' shape,
The heat storage material 400,
Catalytic total organic carbon analysis device, characterized in that it is made up of a plurality of ceramic balls and is received by the groove portion (300a) and is stored by heat generated by the heater (28). The method of claim 4,
The supply pipe 161,
One end is connected to the storage tank 110 and the analysis water is supplied from the outside to the other end, the analysis water passing through the interior between both ends passing through the groove portion 300a is heated by the heat storage material 400 and the storage tank ( 110) is characterized in that the non-catalytic total organic carbon analysis device.

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