KR102401980B1 - A gas absorption pretreatment device for analysis of liquid sample and liquid sample automatic measurement apparatus having thereof - Google Patents

Abstract

A gas absorption pretreatment device according to an aspect of the present invention comprises: a heating reactor in which a sample is stored and includes a heater for heating the sample; a gas absorption reactor for accommodating the gas generated in the heating reactor in a liquid state; and a connector connecting the heating reactor and the gas absorption reactor, wherein a connection passage connecting the heating reactor and the gas absorption reactor is formed inside the connector, and the gas absorption reactor may include a gas permeable tube connected to the connection passage and passing gas. The present invention enables high accuracy and precision analysis in a short time using a small amount of samples and reagents.

Description

A GAS ABSORPTION PRETREATMENT DEVICE FOR ANALYSIS THERAPY LIQUID SAMPLEICUREAND LIQUIHAUTOMING AT LIQUID SAMPLE UREAND LIQUIHAUTOMING AT LEAST LIQUID SAMPLE UREAND LIQUIHAUTARVINGAT for liquid sample analysis

The present invention relates to a gas absorption pretreatment device for converting a substance of interest having volatility in a liquid, a sample, and a form capable of analysis, and an automatic measuring device including the same.

Analysis of liquid 　 samples goes through 　 processes such as 　 sample and reagent injection, chemical reaction, signal detection, waste liquid discharge, washing, etc. Achieving high accuracy and precision of analysis requires a device capable of automatically performing the above-described series of processes.

Based on the technical background as described above, the present invention can use a small amount of sample and reagent to analyze high accuracy and precision at a short time, and to minimize the amount of analysis error and waste generated due to the pollution of the euro. A liquid sample automatic measurement device is provided for analysis of liquid samples, gas absorption, pre-treatment, and a device including them.

A gas absorption pretreatment apparatus according to an aspect of the present invention includes a heating reactor including a heater for storing a sample and heating the sample, a gas absorption reactor for accommodating the gas generated in the heating reactor in a liquid state, the heating reactor and the gas and a connector for connecting the absorption reactor, wherein a connection passage connecting the heating reactor and the gas absorption reactor is formed in the connector, the gas absorption reactor is connected to the connection passage and a gas permeable tube through which gas passes may include

The gas-permeable tube according to an aspect of the present invention may be made of a material having hydrophobicity.

The gas-permeable tube according to an aspect of the present invention may be provided with a pressure adjusting member for adjusting the internal pressure of the gas-permeable tube.

An absorption solution for absorbing gas may be stored in the gas absorption reactor according to an aspect of the present invention.

The connector according to an aspect of the present invention may be connected to the outer peripheral surface of the gas absorption reactor.

The connecting passage according to an aspect of the present invention may include a first connecting portion extending in a height direction of the heating reactor and a second connecting portion extending laterally from the first connecting portion.

The gas-permeable tube according to an aspect of the present invention may include a bent portion positioned lower than the portion connected to the connector.

The gas-permeable tube according to an aspect of the present invention may include a winding wound spirally.

The gas absorption reactor according to an aspect of the present invention may further include a reaction vessel into which the gas permeable tube is inserted, and a stopper for supporting the gas permeable tube may be installed at an upper portion of the reaction vessel.

A liquid sample automatic measurement apparatus according to an aspect of the present invention includes a manifold including a plurality of inlets for introducing a reagent and a washing solution, and a valve installed at the inlets to control the movement of the reagent and washing solution, and is connected to the manifold and a gas absorption pretreatment device including a heating reactor for receiving and heating a sample, a gas absorption reactor for accommodating the gas generated in the heating reactor in a liquid state, and a connector for connecting the heating reactor and the gas absorption reactor, and the gas and a detector for receiving and detecting a sample from the absorption pretreatment device, a connection passage connecting the heating reactor and the gas absorption reactor is formed in the connector, and the gas absorption reactor is connected to the connection passage and provides gas It may include a gas permeable tube that is permeable.

As mentioned above, the gas absorption pretreatment device according to this aspect of the invention has a short gas transport distance and a large contact area between the gas permeable tube and the absorbent liquid, so that a high conversion rate can be obtained in a short time, thereby minimizing the analysis time.

In addition, it is possible to accurately analyze a substance of interest that is converted to a gaseous form by reaction with a reagent or heating at room temperature without loss.

In addition, it is possible to transfer gas by means of water vapor pressure by heating without a separate gas transfer device.

In addition, by varying the length of the heating reactor or connector, it is possible to control the water vapor pressure for gas transport and the degree to which water vapor is condensed in the heating reactor.

In addition, the detectable range and detection sensitivity can be adjusted by adjusting the volume of the gas absorbing solution.

In addition, as only gas selectively permeates through the gas permeable tube, it is possible to minimize the decrease in analytical sensitivity caused by an increase in the volume of the absorption solution due to the condensation of water vapor.

In addition, even if the water vapor condensed in the gas permeable tube is accumulated, it is possible to recover it to the heating reactor without a separate solution transfer device due to a decrease in pressure inside the heating reactor due to a temperature drop after heating is completed.

1 is a block diagram illustrating an automatic liquid sample measurement apparatus according to a first embodiment of the present invention.
2 is a view showing a gas absorption pretreatment apparatus according to a first embodiment of the present invention.
3 is a view showing a gas absorption pretreatment apparatus according to a second embodiment of the present invention.
4 is a view showing a gas absorption pretreatment apparatus according to a third embodiment of the present invention.

Since the present invention can apply various transformations and can have various embodiments, specific embodiments are illustrated and described in detail in the detailed description. However, this is not intended to limit the present invention to specific embodiments, and should be understood to include all modifications, equivalents, and substitutes included in the spirit and scope of the present invention.

The terms used in the present invention are only used to describe specific embodiments, and are not intended to limit the present invention. The singular expression includes the plural expression unless the context clearly dictates otherwise. In the present invention, terms such as 'comprise' or 'have' are intended to designate that the features, numbers, steps, operations, components, parts, or combinations thereof described in the specification exist, and one or more other features It should be understood that this does not preclude the existence or addition of numbers, steps, operations, components, parts, or combinations thereof.

Hereinafter, preferred embodiments of the present invention will be described in detail with reference to the accompanying drawings. In this case, it should be noted that in the accompanying drawings, the same components are denoted by the same reference numerals as much as possible. In addition, detailed descriptions of well-known functions and configurations that may obscure the gist of the present invention will be omitted. For the same reason, some components are exaggerated, omitted, or schematically illustrated in the accompanying drawings.

Hereinafter, a liquid sample automatic measurement apparatus according to a first embodiment of the present invention will be described.

1 is a block diagram illustrating an automatic liquid sample measurement apparatus according to a first embodiment of the present invention, and FIG. 2 is a diagram illustrating a gas absorption pretreatment apparatus according to a first embodiment of the present invention.

1 and 2, the liquid sample automatic measurement device 101 according to the present embodiment includes a manifold 110, a first pump 121, a second pump 122, and a gas absorption pretreatment device ( 201), detector 160, first flow path 141, sample flow path 171, second flow path 142, third flow path 143, fourth flow path 144, first discharge flow path 145, A second discharge flow path 146 may be included.

The manifold 110 controls the flow of fluids such as reagents, cleaning solutions, and air. A plurality of inlets 113 for introducing a reagent are installed in the manifold 110 , and a solenoid valve 114 for controlling the flow of a fluid may be installed in each inlet 113 . An internal passage 112 extending in a straight line is formed in the manifold 110 , and a plurality of inlets 113 are connected to the internal passage 112 .

A solenoid valve 114 is installed at each inlet, and the inflow amount of the reagent may be controlled by the opening time of the solenoid valve 114 . The opening time of the solenoid valve 114 can be adjusted as short as 0.001 seconds, and thus the flow rate of the reagent can be controlled remarkably precisely compared to the prior art.

Air may be introduced through the air inlet by the first pump 121 , and a negative pressure may be formed by the first pump 121 , and air may be sucked into the manifold 110 through this. The introduced air may push the reagent and the sample to the gas absorption pretreatment device 201 or the detector 160 . Accordingly, the supply amount of the reagent and the sample can be controlled by air.

When the portion connected to the first flow path 141 is referred to as the front, the air inlet 113 may be located at the rearmost part of the manifold 110 . Accordingly, after the reagents and samples are supplied, all of the reagents and samples remaining in the first flow path 141 may be pushed out using air.

The first flow path 141 is formed of a pipe connected to the manifold 110 , and transfers reagents and samples to a gas absorption pretreatment device or a detector. The first pump 121 is connected to the first flow path 141 to move the liquid in two directions. The first pump 121 may be a peristaltic pump, and thus, it is possible to prevent the inside of the first pump 121 from being contaminated by the sample and reagent, and to precisely control the input amount of the sample and reagent.

The sample flow path 171 is installed to be connected to the first flow path 141 , and is connected to the first flow path 141 between the first pump 121 and the manifold 110 . The sample flow path 171 is connected to the first flow path 141 via the three-way valve 151 and transfers the sample in a liquid state to the first flow path 141 . The sample flow path 171 may be connected to the water tank 300 in which the sample is stored to supply the sample.

As in the present embodiment, when the sample flow path 171 is installed between the manifold 110 and the first pump 121 , it is possible to prevent the manifold 110 from being contaminated by the sample analyzed in priority.

As shown in FIG. 2 , the gas absorption pretreatment device 201 includes a heating reactor 210 for heating a sample, a gas absorption reactor 230 for absorbing a vaporized sample, a heating reactor 210 and a gas absorption reactor 230 . It may include a connector 240 for connecting the.

The heating reactor 210 is connected to the first flow path 141 to receive reagents and samples from the first flow path 141 . Reagents and samples may be mixed in the heating reactor 210 . The air introduced into the heating reactor 210 through the first pump 121 may mix reagents and samples. However, the present invention is not limited thereto, and the sample and reagent may be mixed in a separate device and then introduced into the heating reactor 210 .

The heating reactor 210 may include a reaction vessel 215 in which samples and reagents are stored and a heater 211 for heating the reaction vessel 215 . In addition, the heating reactor 210 may further include a temperature sensor for temperature measurement and a cooling fan for cooling.

The heating reactor 210 may not only mix and react a sample and a reagent, but also heat the sample to convert a substance of interest into a gas. The conversion of the substance of interest in the liquid sample to a gas is possible only by heating without reaction with the reagent, and the reagent may be made of various substances. The reaction vessel 215 is formed in a tube shape for accommodating a sample and a reagent, and may be formed of heat-resistant glass having light transmittance. However, the present invention is not limited thereto, and the reaction vessel 215 may be made of metal, plastic, ceramic, or the like. A connector 240 through which gas is discharged may be connected to the upper portion of the reaction vessel 215 .

The heater 211 generates heat to heat the reaction vessel 215 , and may have various structures such as a structure including a heating wire and an induction heating structure, but the present invention is not limited to the structure of the heater. The heater 211 may be installed to heat the lower portion of the heating reactor 210 .

The connector 240 connects the heating reactor 210 and the gas absorption reactor 230 , and transfers the gas generated in the heating reactor 210 to the gas absorption reactor 230 . A connection passage 241 passing through the connector 240 is formed, and the gas generated in the heating reactor 210 may be transferred to the gas absorption reactor 230 through the connection passage 241 . The lower end of the connector 240 may be coupled to the upper end of the heating reactor 210 , and the upper end of the connector 240 may be coupled to the lower end of the gas absorption reactor 230 .

The second flow path 142 is connected to the first flow path 141 to supply the absorption liquid transferred from the first flow path 141 to the gas absorption reactor 230 . The absorbent liquid may be made of various materials.

The gas absorption reactor 230 receives the gas generated in the heating reactor 210 in a liquid state. The gas absorption reactor 230 includes a reaction vessel 232 and a gas permeable tube 231 inserted into the reaction vessel 232 . A stopper 239 is installed on the upper portion of the reaction vessel 232 , the gas-permeable tube 231 is installed to pass through the stopper 239 , and the stopper 239 may support the gas-permeable tube 231 . The gas permeable tube 231 is inserted into and penetrates the gas absorption reactor 230, and may be made of a porous material having hydrophobicity.

Even if there is a liquid in the gas-permeable tube 231 having hydrophobicity, only the vaporized gas can selectively permeate and be absorbed by the absorbent liquid. Accordingly, it is possible to prevent a decrease in analytical sensitivity due to dilution resulting from an increase in the absorption liquid due to the condensed water vapor. The gas permeable tube 231 may be formed of a flexible tube, and may be formed in a straight line or a curved line.

A pressure regulating member 235 for regulating the pressure inside the gas absorption reactor 230 is installed in the gas permeable tube 231 . The pressure adjusting member 235 may be formed in the form of a valve. When the pressure adjusting member 235 is installed in the gas-permeable tube 231 as in the present embodiment, it is possible to adjust the gas flowing into the gas-permeable tube 231 to smoothly move into the absorption liquid.

The analysis of the substance of interest (A) in which the substance of interest exists in an ionic state (A ^- ) or in a state bound to another substance (MA) in a liquid sample will be described as an example of the pretreatment reaction process. Here, the substance of interest is easily converted into a gas by reaction with a reagent or heating, and includes arsenic, sulfur, fluorine, cyanide, phenol, ammonia nitrogen, and volatile organic compounds.

The basic reagent is introduced into the gas absorption reactor 230 through the first pump 121 , and then the sample, the acid reagent, and air are introduced into the heating reactor 210 to mix the sample and the reagent. The substance of interest vaporized during the heating reaction under acidic conditions flows into the gas permeable tube 231 through the connection passage 241 by the water vapor pressure, and then passes through the gas permeable tube 231 to form ions in the absorption liquid (A ^- ) is absorbed At this time, the water vapor flowing into the gas permeable tube 231 is condensed and falls into the heating reactor 210 . This can be adjusted by changing the inner diameter of the gas permeable tube 231 . When the inner diameter of the gas permeable tube 231 is sufficiently large, the condensed water vapor can be easily recovered to the heating reactor 210 .

In the gas absorption pretreatment device according to the present invention, since the gas absorption reactor 230 and the heating reactor 210 are physically close to each other, the movement distance of the vaporized material of interest is short, and the outer wall of the gas permeable tube 231 is in contact with the absorption liquid. Since the area being used is wide, high-efficiency pretreatment reaction is possible. In addition, it is possible to transfer the substance of interest, which is converted into gas by water vapor pressure by heating, to the gas absorption reactor 230 without a separate gas transfer device.

The upper portion of the reaction vessel 215 exposed to the surroundings has a relatively lower temperature than the lower portion of the reaction vessel 215 , so that water vapor generated during the pretreatment reaction may be condensed at the upper portion of the reaction vessel 215 . Therefore, condensation of water vapor is possible without a cooling device.

The gas absorption reactor 230 is connected to the detector 160 through a third flow path 143 , and the third flow path 143 transfers the absorption liquid in which the substance of interest has been absorbed to the detector 160 . A second pump 122 for transferring the absorption liquid and the washing liquid may be installed in the third flow path 143 . The second pump 122 may be a bidirectional pump capable of moving a fluid in both directions.

The detector 160 receives the absorption liquid and detects the concentration of the substance of interest contained in the absorption liquid. The detector 160 may detect a substance of interest by various methods such as an absorption method, a fluorescence method, and an electrochemical method, and the present invention is not limited to the configuration of the detector.

A fourth flow path 144 connecting the third flow path 143 and the first flow path 141 may be installed in the third flow path 143 . The fourth flow path 144 may supply a reagent for detection to the detector 160 . A third discharge flow path 147 for discharging the surplus sample and a fourth discharge flow path 148 through which the washing solution washing the first flow path 141 is discharged may be connected to the first flow path 141 .

Meanwhile, a first discharge flow path 145 for discharging the solution remaining in the heating reactor 210 may be connected to the first flow path 141 . In addition, after the heating reaction is completed, a washing solution may be injected into the heating reactor 210 , and the washing solution used for washing the heating reactor 210 may be discharged through the first discharge passage 145 .

A second discharge flow path 146 is connected to the detector 160 and installed, and the solution used for detection and the solution used for washing the gas absorption reactor 230 and the detector 160 pass through the second discharge flow path 146 . can be discharged. After the detection is completed, the washing solution is supplied to the gas absorption reactor 230 , and the washing solution discharged from the gas absorption reactor 230 may be discharged through the second discharge passage 146 after washing the detector 160 . .

As described above, according to this embodiment, the heating reactor 210 and the gas absorption reactor 230 are connected via a connector, and since the gas absorption reactor 230 includes a gas permeable tube 231 having hydrophobicity, the vaporized The substance of interest can be easily absorbed and analyzed in the gas absorption reactor 230 .

Hereinafter, a gas absorption pretreatment apparatus according to a second embodiment of the present invention will be described.

3 is a view showing a gas absorption pretreatment apparatus according to a second embodiment of the present invention.

Referring to FIG. 3 , the gas absorption pretreatment device 202 according to the present embodiment includes a heating reactor 210 for heating a sample, a gas absorption reactor 230 for absorbing a vaporized sample, and a heating reactor 210 , A connector 250 for connecting the gas absorption reactor 230 may be included.

The heating reactor 210 may include a reaction vessel 216 in which samples and reagents are stored and a heater 211 heating the reaction vessel. In addition, the heating reactor 210 may further include a temperature sensor for temperature measurement and a cooling fan for cooling.

The heating reactor 210 may not only mix and react a sample and a reagent, but also heat the sample to convert the substance of interest into a form that can be analyzed. The reaction vessel 216 has a tubular shape for accommodating a sample and a reagent, and may be made of metal, plastic, ceramic, or the like. The heater 211 may include a hot wire, a hot plate, or may have various structures.

The connector 250 connects the heating reactor 210 and the gas absorption reactor 230 , and transfers the gas generated in the heating reactor 210 to the gas absorption reactor 230 . The lower end of the connector 250 may be coupled to the upper end of the heating reactor 210 , and the upper end of the connector 250 may be coupled to the outer peripheral surface of the gas absorption reactor 230 .

The connector 250 may be formed in a tubular shape with an upper portion protruding laterally. A connection passage 251 passing through the inside is formed in the connector 250 , and the gas generated in the heating reactor 210 may be transferred to the gas absorption reactor 230 through the connection passage 251 .

When the second connection part 253 is formed in the connector 250 as in the present embodiment, water vapor contained in the gas transferred from the first connection part 252 may be condensed in the second connection part 253 and move downward again. Accordingly, the amount of water vapor introduced into the gas permeable tube 233 may be reduced.

The gas absorption reactor 230 includes a reaction vessel 232 and a gas permeable tube 233 inserted into the reaction vessel 232 . A connector 250 may be coupled to the outer peripheral surface of the reaction vessel 232 .

A stopper 239 is installed on the upper portion of the reaction vessel 232 , the gas-permeable tube 231 is installed to pass through the stopper 239 , and the stopper 239 may support the gas-permeable tube 231 . A third flow path 143 for discharging the lower portion of the reaction vessel 232 may be connected.

The gas permeable tube 233 may be made of a porous material having hydrophobicity. A pressure adjusting member 235 for regulating the pressure inside the gas absorption reactor 230 is installed at the upper end of the gas permeable tube 233 . The pressure adjusting member 235 may be formed in the form of a valve.

The gas-permeable tube 233 is made of a flexible material, is located further below the portion connected to the connector 251 , and may include a bent portion 233a bent in a U-shape. When there is condensed water vapor in the gas permeable tube 233 during the heating reaction, when the bent portion 233a is formed, it is possible to prevent the condensed water vapor from flowing back into the heating reactor 210 .

Hereinafter, a gas absorption pretreatment apparatus according to a third embodiment of the present invention will be described.

4 is a view showing a gas absorption pretreatment apparatus according to a third embodiment of the present invention.

Referring to FIG. 4 , the gas absorption pretreatment device 203 according to the present embodiment has the same structure as the gas absorption pretreatment device according to the first embodiment, except for the gas permeable tube 234 , and thus has the same structure. A redundant description of the configuration will be omitted.

The gas permeable tube 234 is inserted into and penetrates the gas absorption reactor 230 , and may be made of a porous material having hydrophobicity. The gas permeable tube 234 is made of a flexible material, and may include a spirally connected winding portion 234a. Meanwhile, the winding portion 234a may be wound around a separate member installed inside the gas absorption reactor 230 to maintain a spiral shape.

As described above, when the gas-permeable tube 234 includes the winding portion 234a, the contact area and contact time between the gas-permeable tube 234 and the absorbent liquid increase, so that the absorbent liquid can easily absorb the substance of interest.

In the above, an embodiment of the present invention has been described, but those of ordinary skill in the art can add, change, delete or add components within the scope that does not depart from the spirit of the present invention described in the claims. It will be possible to variously modify and change the present invention by, etc., which will also be included within the scope of the present invention.

101: liquid sample automatic measurement device 110: manifold
121: first pump 122: second pump
141: first euro 142: second euro
143: 3rd euro 144: 4th euro
145: first discharge flow path 146: second discharge flow path
147: third discharge flow path 148: fourth discharge flow path
160: detector 171: sample flow path
201, 202, 203: gas absorption pretreatment unit 210: heating reactor
211: heater 215, 216: reaction vessel
230: gas absorption reactor 231, 233, 234: gas permeable tube
232: reaction vessel 240, 250: connector
241, 251: connection passage 252: first connection part
253: second connection part

Claims (10)

a heating reactor including a heater for storing the sample and heating the sample;
a gas absorption reactor for accommodating the gas generated in the heating reactor in a liquid state;
a connector connecting the heating reactor and the gas absorption reactor;
including,
A connection passage connecting the heating reactor and the gas absorption reactor is formed in the connector,
The gas absorption reactor includes a gas permeable tube connected to the connection passage and allowing gas to pass therethrough,
The connector is connected to the outer peripheral surface of the gas absorption reactor,
The connection passage is a gas absorption preprocessing apparatus for analyzing a liquid sample, characterized in that it includes a first connection portion extending in a height direction of the heating reactor and a second connection portion extending laterally from the first connection portion. According to claim 1,
The gas permeable tube is a gas absorption pretreatment device for liquid sample analysis, characterized in that made of a material having a hydrophobicity. According to claim 1,
A gas absorption pretreatment device for liquid sample analysis, characterized in that the gas permeable tube is provided with a pressure adjusting member for adjusting the internal pressure of the gas permeable tube. According to claim 1,
Gas absorption pre-processing apparatus for liquid sample analysis, characterized in that the absorption solution for absorbing gas is stored in the gas absorption reactor. delete delete a heating reactor including a heater for storing the sample and heating the sample;
a gas absorption reactor for accommodating the gas generated in the heating reactor in a liquid state;
a connector connecting the heating reactor and the gas absorption reactor;
including,
A connection passage connecting the heating reactor and the gas absorption reactor is formed in the connector,
The gas absorption reactor includes a gas permeable tube connected to the connection passage and allowing gas to pass therethrough,
The gas permeable tube includes a curved bent portion,
The bent portion is located further below the portion connected to the connector, and the gas absorption pretreatment device for analyzing a liquid sample, characterized in that it prevents a reverse flow of condensed water vapor. According to claim 1,
The gas permeable tube is a gas absorption pre-processing apparatus for analyzing a liquid sample, characterized in that it comprises a winding wound spirally. According to claim 1,
The gas absorption reactor further includes a reaction vessel into which the gas permeable tube is inserted, and a stopper for supporting the gas permeable tube is installed at an upper portion of the reaction vessel. a manifold including a plurality of inlets for introducing a reagent and a washing solution and a valve installed at the inlets to control movement of the reagent and washing solution;
Gas absorption pretreatment comprising a heating reactor connected to the manifold and heating by receiving a sample, a gas absorption reactor receiving the gas generated in the heating reactor in a liquid state, and a connector connecting the heating reactor and the gas absorption reactor Device; and
a detector for receiving and detecting a sample from the gas absorption pre-processing device;
including,
A connection passage connecting the heating reactor and the gas absorption reactor is formed in the connector,
The gas absorption reactor includes a gas permeable tube connected to the connection passage and allowing gas to pass therethrough,
The connector is connected to the outer peripheral surface of the gas absorption reactor,
The connection passage is a liquid sample automatic measurement device, characterized in that it comprises a first connection portion extending in a height direction of the heating reactor and a second connection portion extending laterally from the first connection portion.

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