KR102655506B1 - Apparatus for removing water in the gas sample - Google Patents

Abstract

In a device for removing moisture from a gas sample containing moisture, the moisture contained in the gas is frozen so that moisture from the gas sample can be removed continuously without changing the gas sample trap and nozzle while removing ice particles frozen in the pipe body. An ice forming unit 100 is provided to remove the ice, and the ice forming unit is provided with a tube body 110 and a temperature controller 130 that lowers the temperature inside the tube body 110 to below zero, thereby adjusting the internal temperature of the tube body. Moisture removal of a gas sample, characterized by passing a gas sample containing moisture through the tube body while maintaining the temperature below zero, removing the moisture contained in the gas by changing its phase to ice, and recovering the gas sample from which the moisture has been removed. Provides a device.

Description

Apparatus for removing moisture from gas samples {APPARATUS FOR REMOVING WATER IN THE GAS SAMPLE}

The present invention relates to a device for removing moisture from a gas sample containing moisture. More specifically, the device for removing moisture from a gas sample continuously removes moisture from the gas sample while removing ice particles from the frozen pipe body. However, it is about a method of continuously removing moisture from a gas sample without replacing the gas sample trap and nozzle while removing ice particles from the frozen pipe body.

When analyzing multiple samples, if the sample is supplied to the analysis equipment while containing moisture, the moisture will adversely affect the analysis. To prevent this, the moisture must be removed before supplying the sample to the analysis equipment. do.

As a method for removing moisture from a sample, methods using moisture absorbing materials and methods using temperature changes have been proposed.

However, it is difficult to effectively remove moisture using the above methods alone, and to solve this problem, a method using a plurality of refrigeration dehumidification means as shown in FIG. 1 has been proposed.

The moisture removal device shown in FIG. 1 is formed with a solenoid valve (21*) that selectively opens a sample storage portion (10*) where the sample is stored and a discharge portion (22*) through which accumulated moisture is discharged by controlling the temperature. First dehumidification unit (20*); a supply pump (30*) that supplies a sample to the first dehumidification unit; a second dehumidifying unit (40*) and a third dehumidifying unit (50*) sequentially provided so that the sample that has passed through the first dehumidifying unit (20*) is transferred, the temperature is adjusted, and moisture is collected on the inner wall; It is formed including.

In the moisture removal device, the sample is transferred to the inner lower part of the double pipe structure by the supply pump, moves from the lower part to the outside, moves to the upper part, and is discharged to the outside. Moisture accumulates in the lower part by temperature control.

At this time, when the supply pump operates, a high pressure is formed inside the first dehumidification unit by the supply pump, so a solenoid valve is formed in the outlet to prevent the sample from being discharged through the outlet along with moisture. , the solenoid valve is equipped with a timer to regularly remove moisture accumulated on the lower side.

However, although the first to third dehumidifying units are provided to remove moisture through temperature control, a plurality of dehumidifying units are formed, and a means for controlling the temperature must be provided for each, so the volume occupied by the second dehumidifying unit is inevitably increased. Since the dehumidifying unit and the third dehumidifying unit must be maintained at a temperature of -20 ℃ and -60 ℃, respectively, a lot of energy is required to maintain this, and the sample and moisture that passed through the first dehumidifying unit must pass through the second and third dehumidifying units. However, since these dehumidifiers are kept below freezing, moisture freezes inside the trap, blocking the tube, causing a problem in which the sample cannot pass, so the moisture trap must be replaced frequently, and it is greatly affected by surrounding factors such as atmospheric humidity. There is a problem that the moisture removal effect varies.

Meanwhile, in Korean Patent Publication No. 10-2012-0013098 (name: moisture removal system in corrosive gas scrubber), as described in the publication, a distribution means for selectively distributing incoming analysis samples to a plurality of lines and the above A moisture removal system is described that includes a pair of dehumidifying means installed in a plurality of lines to remove moisture from the sample, and uses a controller to selectively inject the sample into each line and dehumidify it at the same time.

Accordingly, moisture is alternately and continuously removed through a double structure of exhaust gas containing a large amount of corrosive gas emitted during a semiconductor process or chemical process.

And, in Korean Patent Registration No. 10-1508972 (name: Dehumidifying device for scrubber with thermally conductive plastic cooling pipe), as described in the gazette, harmful gases containing toxic gas flowing in from the main equipment through a vacuum pump are used. It is installed integrally with a scrubber that purifies gas and discharges it into the exhaust duct, or is installed in the exhaust duct, and includes an inlet through which exhaust gas discharged from the scrubber flows, a dehumidifying space in communication with the inlet, and the dehumidifying space and the exhaust. It includes a dehumidifying chamber equipped with an outlet for communicating with the duct, and a plurality of heat conductive plastic cooling pipes installed in multiple stages in the dehumidifying space of the dehumidifying chamber to cool and condense the toxic gas contained in the exhaust gas flowing into the dehumidifying space. A dehumidifying device is described.

Another prior art is introduced through Figures 2.3, the moisture removal device (1^) has a moving space inside which corrosive gas is transferred, and an inlet (11^) that introduces corrosive gas into the moving space and to the outside. A chamber (10^) having a discharge port (12^) for discharging and an outlet (13^) for discharging condensed water condensed in the moving space, and a heat supply means (20^) for supplying heat to the chamber (10^). ) has.

That is, the chamber 10^ receives the cooling heat generated from the heat supply means 20^ and condenses it through heat exchange with the corrosion gas moving in the moving space to condense the moisture contained in the corrosion gas. In particular, it is applied to remove moisture contained in corrosive gases emitted from semiconductor manufacturing processes or chemical processes, and prevents corrosive gases from entering analysis equipment while containing moisture.

The condensed water condensed in this way is discharged through the outlet (13^) and treated separately.

In this prior art, in the moisture removal device 1^ for corrosive gas, the chamber 10^ is provided with an inlet 11^ and an outlet 12^ with a gap at the top, respectively, and is provided inside. The moving space is formed to communicate with the inlet (11^) and the discharge port (12^), and has a 'barrel' shaped body (14^) provided at the bottom with the outlet (13^) communicating with the moving space. .

That is, the corrosive gas flowing in through the inlet (11^) moves to the outlet (12^) and condenses while being discharged, and the condensed water is discharged through the outlet (13^).

Accordingly, in the moisture removal device (1^), in the moving space of the body (14^), the inlet (11^) and the discharge port (12^) are partitioned and separated, but a part of the lower part is communicated to prevent corrosive gas. A partition 15^ is provided to move from the inlet 11^ to the outlet 12^.

However, such condensate may freeze on the pipe and cause problems, so a device for removing moisture from a water-containing gas sample requires a method that can continuously remove moisture from the gas sample while removing ice particles from the frozen pipe. do.

Additionally, a method is required to continuously remove moisture from a gas sample without replacing the gas sample trap and nozzle while removing ice particles from the frozen pipe body.

For reference, when explaining the prior art, it is stated that * or ^ is used as a subscript along with the drawing number to avoid duplicate listing of drawing numbers.

1. Korean Patent Registration No. 10-0922630 2. Korean Patent Registration No. 10-1667882 3. Korean Patent Publication No. 10-2012-0013098 4.Korean Patent Registration No. 10-1508972

In order to solve the above problems, the purpose of the present invention is to continuously remove moisture from the gas sample while removing ice particles from the frozen pipe body in an apparatus for removing moisture from a gas sample containing moisture. The purpose is to provide a moisture removal device that can

Another object of the present invention is to provide a moisture removal device that can continuously remove moisture from a gas sample without replacing the gas sample trap and nozzle while removing ice particles from the frozen pipe body.

The technical problems that this application seeks to solve are not limited to those described above.

In order to solve the above technical problem, the present invention provides a device for removing moisture from a gas sample containing moisture, wherein the device is provided with an ice forming unit 100 that freezes and removes moisture contained in the gas, wherein the ice forming unit The tube body 110 and a temperature controller 130 that lowers the temperature inside the tube body 110 to below zero are provided, and a gas sample containing moisture passes through the tube body while maintaining the internal temperature of the tube body below zero. This is characterized in that the moisture contained in the gas is removed by changing its phase to ice, thereby recovering the gas sample from which the moisture has been removed.

At this time, ice grains generated due to a phase change of moisture adhere to the inner surface of the tube body, and the device is characterized by being equipped with an ice removal unit for removing ice grains from the inner surface of the tube body.

In addition, a plate 120 surrounding the pipe body is provided, and the temperature controller 130 is attached to the plate to control the temperature inside the pipe body by changing the temperature of the plate to below or above zero. At this time, the material of the pipe body is glass. Or, it may be made of stainless steel.

In addition, ice removal raises the temperature of the plate to zero by the temperature controller, so that the temperature of the inner surface becomes zero, ice grains adhering to the inner surface are separated from the inner surface, and compressed gas is distributed through the internal passage. It is characterized in that the ice particles that melt while being separated are removed by introducing them into the .

In addition, the ice forming part 100 is formed of a first ice forming part 100a and a second ice forming part 100b to collect moisture from the gas sample through the first pipe body 110a of the first ice forming part 100a. As ice particles accumulate in the internal passage of the first pipe and become narrow as it is removed, the ice particles in the first pipe are removed through the ice removal unit, and at the same time, moisture in the gas sample is removed through the second ice forming unit, and then again through the second ice forming unit. When ice particles accumulate in the internal passage of the second pipe body (110b) of (100b) and become narrow, the ice particles in the internal passage of the second pipe body are removed through the ice removal unit and at the same time, gas is passed through the first pipe body (110a) of the first ice forming unit. It is characterized by continuously removing moisture from the gas sample by removing moisture from the sample.

In addition, a gas sample is supplied to the first pipe body of the first ice forming unit and the second pipe body of the second ice forming unit through one gas sample inlet (A), and the gas from which moisture has been removed is passed through the first pipe body and the second pipe body. As the sample is formed to be discharged through one gas sample outlet (B), the gas sample is continuously supplied alternately to the first pipe body and the second pipe body without changing the gas sample inlet, and the gas sample is supplied alternately from the first pipe body and the second pipe body. As the gas sample from which the moisture has been removed is discharged through one gas sample outlet, the gas sample from which the moisture has been removed is discharged continuously without changing the gas sample outlet.

In addition, as the first valve (1) is disposed at the gas sample inlet (A), the first valve (1a) is directly connected to the gas sample inlet, and the first valve (1b) is connected to the gas sample inlet (1b). The first pipe inlet (110a1) of the first pipe body (110a) is in communication, and the 1c port (1c) of the first valve is in communication with the second pipe inlet (110b1) of the second pipe body (110b) and the gas sample inlet. (A) connects the first pipe body inlet (110a1) and the second pipe body inlet (110b1) through the one 1_3 wear valve, and the second valve (2) is disposed at the gas sample outlet. The second a port (2a) of the valve is directly connected to the gas sample outlet (B), and the second b port (2b) of the second valve is in communication with the first pipe outlet (110a2) of the first pipe body (110a). The second c port (2c) of the second valve is connected to the second pipe outlet (110b2) of the second pipe body (110b), and the gas sample outlet (B) is connected to the first pipe outlet (110a2) through the one second valve. It is characterized in that it connects the second pipe outlet (110b2).

In addition, the first pipe body of the first ice forming part and the second pipe body of the second ice forming part are formed so that compressed air is supplied through one compressed air inlet (C), so that the first pipe body and the second pipe body of the second ice forming part are formed so that compressed air is supplied through one compressed air inlet (C). Supply compressed air to the second pipe body,

The first pipe body of the first ice forming part and the second pipe body of the second ice forming part are formed so that compressed air is discharged through one compressed air outlet (D), so that the first pipe body and the second pipe body of the second ice forming part are formed so that compressed air is discharged through one compressed air outlet (D). It is characterized by discharging ice particles or moisture mixed with moisture discharged from the two pipes through a single compressed air outlet.

In addition, as the fifth valve 5 is disposed between the 1b port (1b) of the first valve and the first pipe inlet (110a1) of the first pipe body (110a), the 1b port (1b) of the first valve ) is connected to the 5b port (5b) of the 5th valve (5), and the 5c port (5c) of the 5th valve (5) is connected to the first pipe inlet (110a1),

As the 6th valve 6 is disposed between the 1c port (1c) of the first valve and the first pipe inlet (110b1) of the second pipe body (110b), the 1c port (1c) of the first valve is connected to the 6b port (6b) of the 6th valve (6), and the 6c port (6c) of the 6th valve (6) is connected to the second pipe inlet (110b1),

As the seventh valve 7 is disposed between the first pipe outlet (110a2) of the first pipe body (110a) and the 2b inlet (2b) of the second valve, the first pipe outlet (110a2) is It is connected to the 7b port (7b) of the 7th valve, and the 7c port (7c) of the 7th valve (7) is connected to the 2b port (2b) of the second valve,

As the eighth valve 8 is disposed between the second pipe outlet (110b2) of the second pipe body (110b) and the second c port (2c) of the second valve, the second pipe outlet (110b2) is It is connected to the 8b port (8b) of the 8th valve, and the 8c port (8c) of the 8th valve 8 is connected to the 2c port (2c) of the second valve, so that the compressed air flows into the first pipe and It is characterized by having a passage supplied to the second pipe body.

In addition, as the third valve (3) is disposed at the compressed air inlet (C), the third a port (3a) of the third valve is directly connected to the compressed air inlet, and the third b port (3b) of the third valve (3) is directly connected to the compressed air inlet. ) communicates with the 5a port (5a) of the 5th valve (5), and the 3c port (3c) of the 3rd valve (3) communicates with the 6a port (6a) of the 6th valve (6) ,

As the fourth valve (4) is disposed at the compressed air outlet (D), the 4th valve (4a) is directly connected to the compressed air outlet, and the 4th valve (4b) of the fourth valve (4) is directly connected to the compressed air outlet. communicates with the 7a port (7a) of the 7th valve (7), and the 4c port (4c) of the 4th valve (4) communicates with the 8a port (8a) of the 8th valve (8), The compressed air is characterized in that it is provided with a passage through which the compressed air is supplied to the first pipe body and the second pipe body.

In addition, when a gas sample containing moisture is supplied to the first pipe 110a and the moisture is removed, the 1c port of the first valve, the 5a port of the 5th valve, the 7th port of the 7th valve, and the 2nd valve Port 2c is turned off, ports 1a and 1b of the first valve, ports 5b and 5c of the 5th valve, ports 7b and 7c of the 7th valve, and ports 2a and 2 of the second valve. District 2b is on

The gas sample containing moisture supplied from the gas sample inlet (A) passes through ports 1a and 1b of the first valve, then passes through ports 5b and 5c of the fifth valve, and then passes through the first pipe ( Moisture is removed while passing through 110a), passes again through ports 7b and 7c of the 7th valve, and is discharged to the gas sample outlet (B) through ports 2b and 2a of the second valve. The first pipe body 110a is characterized in that it is managed to remain below freezing.

In addition, when moisture is removed from a gas sample containing moisture through the first pipe body (110a), compressed air is supplied to the second pipe body (110b) to remove grains formed inside the second pipe body, and at this time, the third pipe body (110b) is supplied with compressed air. Port 3b of the valve, port 6b of the 6th valve, port 8c of the 8th valve, and port 4b of the 4th valve are turned off, ports 3a and 3c of the 3rd valve, and ports 6a and 6 of the 6th valve. Port 6c, ports 8b and 8a of the 8th valve, ports 4c and 4a of the 4th valve are turned on, and the compressed air supplied from the compressed air inlet (C) flows through ports 3a and 3 of the 3rd valve. After communicating with the 3c port and the 6a and 6c ports of the 6th valve, ice particles or moisture are removed while passing through the second pipe body (110b), and then the 8b and 8a ports of the 8th valve and the 4th valve are connected. It is discharged to the compressed air outlet (D) through the 4th c and 4a ports, and at this time, the second pipe body 110b is controlled to be maintained at an image level.

In addition, when a gas sample containing moisture is supplied to the second pipe body (110b) and the moisture is removed, the 1b port of the first valve, the 6a port of the 6th valve, the 8a port of the 8th valve, and the 2nd valve port Port 2b is turned off, ports 1a and 1c of the first valve, ports 6b and 6c of the 6th valve, ports 8b and 8c of the 8th valve, and ports 2a and 2 of the second valve. When port 2c is turned on, the gas sample containing moisture supplied from the gas sample inlet (A) passes through ports 1a and 1c of the first valve and then through ports 6b and 6c of the sixth valve. Afterwards, moisture is removed while passing through the second pipe body (110b), and again passes through ports 8b and 8c of the 8th valve, and then passes through ports 2c and 2a of the second valve to the gas sample outlet (B). ), and at this time, the second pipe body (110b) is characterized in that it is managed to be maintained below freezing.

In addition, when moisture is removed from a gas sample containing moisture through the second pipe body (110b), compressed air is supplied to the first pipe body (110a) to remove grains formed inside the first pipe body, and at this time, the third pipe body (110a) is supplied with compressed air. Port 3c of the valve, port 5b of the 5th valve, port 7c of the 7th valve, and port 4c of the 4th valve are turned off, ports 3a and 3b of the 3rd valve, and ports 5a and 5 of the 5th valve. Port 5c, ports 7b and 8a of the 7th valve, ports 4b and 4a of the 4th valve are turned on, and the compressed air supplied from the compressed air inlet (C) flows through ports 3a and 3 of the 3rd valve. After communicating with the 3b port and the 5a and 5c ports of the 5th valve, ice particles or moisture are removed while passing through the first pipe body (110a), and then the 7b and 8a ports of the 7th valve and the 4th valve are connected. It is discharged to the compressed air outlet (D) through the 4b port and 4a port, and at this time, the first pipe body (110a) is controlled to be maintained at an image level.

In addition, a first plate 120a surrounding the first pipe body is provided as a medium for raising or lowering the temperature of the first pipe body, and a first temperature controller for raising or lowering the temperature of the first plate 120a ( 130a) utilizes a thermoelectric element whose temperature drops when power is applied and the temperature rises when power is turned off, and is provided with a second plate (120b) surrounding the second pipe body as a medium for raising or lowering the temperature of the second pipe body. The second temperature controller 130b for raising or lowering the temperature of the second plate 120b is characterized by using a thermoelectric element whose temperature drops when power is applied and the temperature rises when power is turned off.

According to an embodiment of the present application, the present invention is a device for removing moisture from a gas sample containing moisture, which can continuously remove moisture from the gas sample while removing ice particles from the frozen pipe body. It works.

In addition, while removing ice particles from the frozen pipe body, it is effective in continuously removing moisture from the gas sample without replacing the gas sample trap and nozzle.

1 to 3 are schematic diagrams showing a conventional moisture removal device.
Figure 4 is a schematic diagram showing a device for removing moisture from a gas sample according to the present invention.
Figure 5 is a schematic diagram showing the gas sample moisture removal process in the first pipe according to the present invention.
Figure 6 is a schematic diagram showing the gas sample moisture removal process in the second pipe according to the present invention.

Hereinafter, preferred embodiments of the present invention will be described in detail with reference to the attached drawings. However, the technical idea of the present invention is not limited to the embodiments described herein and may be embodied in other forms. Rather, the embodiments introduced herein are provided so that the disclosed content will be thorough and complete and so that the spirit of the invention can be sufficiently conveyed to those skilled in the art.

In this specification, when an element is referred to as being on another element, it means that it may be formed directly on the other element or that a third element may be interposed between them. Additionally, in the drawings, the thicknesses of films and regions are exaggerated for effective explanation of technical content.

Additionally, in various embodiments of the present specification, terms such as first, second, and third are used to describe various components, but these components should not be limited by these terms. These terms are merely used to distinguish one component from another. Accordingly, what is referred to as a first component in one embodiment may be referred to as a second component in another embodiment. Each embodiment described and illustrated herein also includes its complementary embodiment. Additionally, in this specification, 'and/or' is used to mean including at least one of the components listed before and after.

In the specification, singular expressions include plural expressions unless the context clearly dictates otherwise. In addition, terms such as "include" or "have" are intended to designate the presence of features, numbers, steps, components, or a combination thereof described in the specification, but are not intended to indicate the presence of one or more other features, numbers, steps, or components. It should not be understood as excluding the possibility of the presence or addition of elements or combinations thereof.

Additionally, in the following description of the present invention, if it is determined that a detailed description of a related known function or configuration may unnecessarily obscure the gist of the present invention, the detailed description will be omitted.

According to an embodiment of the present invention, in an apparatus for removing moisture from a gas sample containing moisture, a method is provided for continuously removing moisture from the gas sample while removing ice grains from the frozen pipe body, and providing a method for continuously removing moisture from the gas sample. Provided is a gas sample moisture removal device that can continuously remove moisture from the gas sample without replacing the gas sample trap and nozzle while removing ice particles from the pipe body.

In the conventional process of removing moisture from a gas sample as shown in Figure 1, moisture freezes inside the trap for removing moisture, clogging the tube and preventing the sample from passing, so the moisture trap often needs to be replaced frequently.

Accordingly, the device for removing moisture from a gas sample of the present invention provides a method of continuously removing moisture from a gas sample while removing ice particles from the frozen pipe body.

Additionally, a method is provided that can provide a method of continuously removing moisture from a gas sample without replacing the gas sample trap and nozzle while removing ice particles from the frozen pipe body.

Hereinafter, a method for removing moisture from a moisture-containing gas sample according to the present invention will be described with reference to FIGS. 4 to 6.

The device for removing moisture from a gas sample containing moisture of the present invention shown in FIG. 4 is provided with an ice forming unit 100 that freezes and removes moisture contained in the gas, wherein the ice forming unit includes the tubular body 110 and the A temperature controller 130 is provided to lower the temperature inside the pipe body 110 to below zero, and allows a gas sample containing moisture to pass through the inside of the pipe body while maintaining the internal temperature of the pipe body below zero to be included in the gas. It is characterized in that the gas sample from which the moisture has been removed is recovered by removing the moisture by changing it into ice.

In addition, ice particles generated due to a phase change of moisture adhere to the inner surface of the tube body, and the device includes an ice removal unit for removing ice particles from the inner surface of the tube body.

In addition, a plate 120 surrounding the pipe body is provided, and the temperature controller 130 is attached to the plate to control the temperature inside the pipe body by changing the temperature of the plate to below zero or above zero. At this time, the material of the pipe body is glass. or stainless steel.

At this time, ice removal is performed by raising the temperature of the plate to zero by the temperature controller, so that the temperature of the inner surface becomes zero, ice grains stuck to the inner surface are separated from the inner surface, and compressed gas is supplied through the internal passage. It is characterized in that the ice particles that melt while being separated are removed by introducing them into the .

And the medium for raising or lowering the temperature of the first pipe body is provided with a first plate (120a) surrounding the first pipe body, and a first temperature controller for raising or lowering the temperature of the first plate (120a). (130a) utilizes a thermoelectric element whose temperature drops when power is applied and the temperature rises when power is turned off.

A second plate (120b) surrounding the second pipe body is provided as a medium for raising or lowering the temperature of the second pipe body, and a second temperature controller (130b) is provided for raising or lowering the temperature of the second plate (120b). ) is characterized by using a thermoelectric element whose temperature drops when power is applied and the temperature rises when power is turned off.

Next, as shown in Figure 5, the ice forming part 100 is formed of a first ice forming part 100a and a second ice forming part 100b, and the first pipe body (100b) of the first ice forming part 100a As the moisture of the gas sample is removed through 110a), if ice particles accumulate in the internal passage of the first pipe and become narrow, the ice particles of the first pipe are removed through the ice removal unit and at the same time, the moisture of the gas sample is removed through the second ice forming unit. When ice particles accumulate in the internal passage of the second pipe body (110b) of the second ice forming unit (100b) and become narrow, the ice particles in the internal passage of the second pipe body are removed through the ice removal unit and at the same time, the internal passage of the second pipe body (110b) of the second ice forming unit (100b) is removed. It is characterized by continuously removing moisture from the gas sample by removing moisture from the gas sample through the first pipe body (110a).

Through this, a gas sample is supplied to the first pipe body of the first ice forming unit and the second pipe body of the second ice forming unit through one gas sample inlet (A), and moisture is removed through the first pipe body and the second pipe body. Since the gas sample is formed to be discharged through one gas sample outlet (B), the gas sample is continuously supplied alternately to the first pipe body and the second pipe body without changing the gas sample inlet, and the first pipe body and the second pipe body are supplied alternately. As the gas sample from which the moisture has been removed is discharged through one gas sample outlet, the gas sample from which the moisture has been removed is discharged continuously without changing the gas sample outlet.

Furthermore, the first pipe body of the first ice forming part and the second pipe body of the second ice forming part are formed so that compressed air is supplied through one compressed air inlet (C), so that the first pipe body can be supplied without changing the compressed air inlet (C). And compressed air is supplied to the second pipe body, and the first pipe body of the first ice forming part and the second pipe body of the second ice forming part are formed so that compressed air is discharged through one compressed air outlet (D). It is desirable to discharge ice grains or moisture mixed with moisture discharged from the first and second pipe bodies through one compressed air outlet without changing (D).

As such, the first pipe body and the second pipe body are equipped with respective valves, so that gas samples can be supplied alternately to each pipe body. Specifically, as shown in Figure 2, the gas sample inlet (A) is equipped with a first valve ( As 1) is disposed, the 1st port (1a) of the first valve is directly connected to the gas sample inlet, and the 1st port (1b) of the first valve is connected to the first pipe inlet (110a1) of the first pipe body (110a). ) is communicated, and the 1st port (1c) of the first valve is communicated with the second pipe inlet (110b1) of the second pipe body (110b), and the gas sample inlet (A) is connected through the one 1_3 wear valve. The first pipe inlet (110a1) and the second pipe inlet (110b1) are connected, and as the second valve (2) is disposed at the gas sample outlet, the second a port (2a) of the second valve is the gas sample outlet ( B), and the 2nd b port (2b) of the second valve communicates with the first pipe outlet (110a2) of the first pipe body (110a), and the 2nd c port (2c) of the second valve is connected to the second pipe body (110a). The second pipe outlet (110b2) of the pipe body (110b) is connected so that the gas sample outlet (B) can connect the first pipe body outlet (110a2) and the second pipe body outlet (110b2) through the one second valve.

And as the fifth valve 5 is disposed between the 1b port (1b) of the first valve and the first pipe inlet (110a1) of the first pipe body (110a), the 1b port (1b) of the first valve ) is connected to the 5b port (5b) of the 5th valve (5), and the 5c port (5c) of the 5th valve (5) is connected to the first pipe inlet (110a1),

As the 6th valve 6 is disposed between the 1c port (1c) of the first valve and the first pipe inlet (110b1) of the second pipe body (110b), the 1c port (1c) of the first valve is connected to the 6b port (6b) of the 6th valve (6), and the 6c port (6c) of the 6th valve (6) is connected to the second pipe inlet (110b1),

As the seventh valve 7 is disposed between the first pipe outlet (110a2) of the first pipe body (110a) and the 2b inlet (2b) of the second valve, the first pipe outlet (110a2) is It is connected to the 7b port (7b) of the 7th valve, and the 7c port (7c) of the 7th valve (7) is connected to the 2b port (2b) of the second valve,

As the eighth valve 8 is disposed between the second pipe outlet (110b2) of the second pipe body (110b) and the second c port (2c) of the second valve, the second pipe outlet (110b2) is It is connected to the 8b port (8b) of the 8th valve, and the 8c port (8c) of the 8th valve (8) is connected to the 2c port (2c) of the second valve, so that the compressed air flows into the first pipe. And it is desirable to provide a passage supplying to the second pipe body.

In addition, as the third valve (3) is disposed at the compressed air inlet (C), the third a port (3a) of the third valve is directly connected to the compressed air inlet, and the third b port (3b) of the third valve (3) is directly connected to the compressed air inlet. ) communicates with the 5a port (5a) of the 5th valve (5), and the 3c port (3c) of the 3rd valve (3) communicates with the 6a port (6a) of the 6th valve (6) ,

As the fourth valve (4) is disposed at the compressed air outlet (D), the 4th valve (4a) is directly connected to the compressed air outlet, and the 4th valve (4b) of the fourth valve (4) is directly connected to the compressed air outlet. communicates with the 7a port (7a) of the 7th valve (7), and the 4c port (4c) of the 4th valve (4) communicates with the 8a port (8a) of the 8th valve (8), It is preferable to provide a passage through which the compressed air is supplied to the first pipe body and the second pipe body.

Next, regarding the way the valve operates, the gas sample containing moisture is supplied to the first pipe body (110a) and moisture is removed, and the appearance of moisture being removed by being supplied to the second pipe body (110b) is shown in Figure 5. As shown in Figure 6.

Specifically, when a gas sample containing moisture is supplied to the first pipe body 110a and the moisture is removed, the 1c port of the first valve, the 5a port of the 5th valve, the 7th port of the 7th valve, and the 2nd valve The 2c port is turned off, the 1a and 1b ports of the 1st valve, the 5b and 5c ports of the 5th valve, the 7b and 7c ports of the 7th valve, and the 2a port of the 2nd valve. and section 2b is on

The gas sample containing moisture supplied from the gas sample inlet (A) passes through ports 1a and 1b of the first valve, then passes through ports 5b and 5c of the fifth valve, and then passes through the first pipe ( Moisture is removed while passing through 110a), passes again through ports 7b and 7c of the 7th valve, and is discharged to the gas sample outlet (B) through ports 2b and 2a of the second valve. It is desirable that the first pipe body (110a) is managed to be maintained at a temperature below zero.

When moisture is removed from a gas sample containing moisture through the first pipe body (110a), compressed air is supplied to the second pipe body (110b) to remove grains formed inside the second pipe body, and at this time, the third valve Port 3b, port 6b of valve 6, port 8c of valve 8, and port 4b of valve 4 are turned off, ports 3a and 3c of valve 3, and ports 6a and 6c of valve 6. 8b and 8a ports of the 8th valve, and 4c and 4a ports of the 4th valve are turned on.

The compressed air supplied from the compressed air inlet (C) flows through ports 3a and 3c of the third valve and ports 6a and 6c of the sixth valve, and then passes through the second pipe body (110b) to form ice. Grains or moisture are removed and discharged to the compressed air outlet (D) through ports 8b and 8a of the 8th valve and ports 4c and 4a of the 4th valve. At this time, the second pipe (110b) It is desirable to control it to maintain the image.

Conversely, when a gas sample containing moisture is supplied to the second pipe body (110b) to remove moisture, as shown in Figure 4, the 1b port of the first valve, the 6a port of the 6th valve, and the 8th valve The 8a port and the 2b port of the second valve are turned off, the 1a port and 1c port of the first valve, the 6b port and 6c port of the 6th valve, and the 8b port and 8c port of the 8th valve, Ports 2a and 2c of the second valve are turned on,

The gas sample containing moisture supplied from the gas sample inlet (A) passes through ports 1a and 1c of the first valve, then passes through ports 6b and 6c of the sixth valve, and then passes through the second pipe ( Moisture is removed while passing through 110b), passes again through ports 8b and 8c of the 8th valve, and is discharged to the gas sample outlet (B) through ports 2c and 2a of the second valve. It is preferable that the second pipe body (110b) is managed to maintain a temperature below zero.

And when moisture is removed from the gas sample containing moisture through the second pipe body (110b), compressed air is supplied to the first pipe body (110a) to remove grains formed inside the first pipe body, and at this time, the third pipe body (110b) is supplied with compressed air. Port 3c of the valve, port 5b of the 5th valve, port 7c of the 7th valve, and port 4c of the 4th valve are turned off, ports 3a and 3b of the 3rd valve, and ports 5a and 5 of the 5th valve. The 5c port, the 7b port and 8a port of the 7th valve, and the 4b port and 4a port of the 4th valve are turned on,

The compressed air supplied from the compressed air inlet (C) flows through ports 3a and 3b of the third valve and ports 5a and 5c of the fifth valve, and then passes through the first pipe body (110a) to form ice. Grains or moisture are removed and discharged to the compressed air outlet (D) through ports 7b and 8a of the 7th valve and ports 4b and 4a of the 4th valve. At this time, the first pipe body (110a) It is desirable to control it to maintain the image.

Through this, the present invention, in an apparatus for removing moisture from a gas sample containing moisture, can continuously remove moisture from the gas sample while removing ice particles from the frozen pipe body, and remove ice particles from the frozen pipe body. Provides a gas sample moisture removal device that can continuously remove moisture from the gas sample without replacing the gas sample trap and nozzle during the process.

Above, the present invention has been described in detail using preferred embodiments, but the scope of the present invention is not limited to the specific embodiments and should be interpreted in accordance with the appended claims. Additionally, those skilled in the art should understand that many modifications and variations are possible without departing from the scope of the present invention.

1: 1st valve 2: 2nd valve
3: 3rd valve 4: 4th valve
5: 5th valve 6: 6th valve
7: 7th valve 8: 8th valve
100: ice forming part 100a: first ice forming part
100b: second ice forming part 110: tube body
110a: first pipe body 110b: second pipe body
120: plate 120a: first plate
120b: Second plate 130: Temperature controller
130a: first temperature controller 130b: second temperature controller

Claims (16)

delete delete delete delete delete In a device for removing moisture from a gas sample containing moisture,
The device is provided with an ice forming unit 100 that freezes and removes moisture contained in the gas, and the ice forming unit includes a tube body 110 and a temperature controller 130 that lowers the temperature inside the tube body 110 to below zero. is provided, and a gas sample containing moisture is passed through the inside of the pipe body while maintaining the internal temperature of the pipe body below zero, and the moisture contained in the gas is removed by changing the phase to ice, thereby recovering the gas sample from which the moisture has been removed. And
Ice particles generated due to a phase change of moisture adhere to the inner surface of the tube body, and the device is equipped with an ice removal unit to remove ice particles from the inner surface of the tube body,
Ice removal involves raising the temperature of the plate to zero by the temperature controller, thereby raising the temperature of the inner surface to zero, ice particles adhering to the inner surface are separated from the inner surface, and compressed gas is injected into the internal passage. Remove the ice particles that melt as they separate.
The ice forming unit 100 is formed of a first ice forming unit 100a and a second ice forming unit 100b and removes moisture from the gas sample through the first pipe body 110a of the first ice forming unit 100a. Accordingly, when ice particles accumulate in the internal passage of the first pipe and become narrow, the ice particles of the first pipe are removed through the ice removal unit and at the same time, moisture of the gas sample is removed through the second ice forming unit,
Again, when ice particles accumulate in the internal passage of the second pipe body (110b) of the second ice forming unit (100b) and become narrow, the ice particles in the internal passage of the second pipe body are removed through the ice removal unit and at the same time, the first pipe body of the first ice forming unit (100b) is removed. Continuously remove moisture from the gas sample through (110a).
A gas sample is supplied to the first pipe body of the first ice forming unit and the second pipe body of the second ice forming unit through one gas sample inlet (A), and the gas sample from which moisture has been removed through the first pipe body and the second pipe body Since it is formed to be discharged through one gas sample outlet (B), gas samples are continuously supplied alternately to the first pipe body and the second pipe body without changing the gas sample inlet,
As the gas sample from which moisture has been removed from the first pipe body and the second pipe body is discharged through one gas sample outlet, the gas sample from which moisture has been removed is continuously discharged without changing the gas sample outlet.
As the first valve (1) is disposed at the gas sample inlet (A), the first valve (1a) is directly connected to the gas sample inlet, and the first valve (1b) is directly connected to the gas sample inlet (1b). The first pipe inlet (110a1) of the first pipe body (110a) is in communication, and the first c port (1c) of the first valve is in communication with the second pipe inlet (110b1) of the second pipe body (110b), and the gas sample inlet ( A) connects the first pipe inlet (110a1) and the second pipe inlet (110b1) through the first 1_3 wear valve,
As the second valve (2) is disposed at the gas sample outlet, the second a port (2a) of the second valve is directly connected to the gas sample outlet (B), and the second b port (2b) of the second valve is directly connected to the gas sample outlet (B). The first pipe outlet (110a2) of the first pipe body (110a) is connected, and the second c port (2c) of the second valve is connected to the second pipe outlet (110b2) of the second pipe body (110b), and the gas sample outlet ( B) connects the first pipe outlet (110a2) and the second pipe outlet (110b2) through the one second valve.
The first pipe body of the first ice forming part and the second pipe body of the second ice forming part are formed so that compressed air is supplied through one compressed air inlet (C), so that the first pipe body and the second pipe body of the second ice forming part are formed so that compressed air is supplied through one compressed air inlet (C). 2 Supply compressed air to the pipe body,
The first pipe body of the first ice forming part and the second pipe body of the second ice forming part are formed so that compressed air is discharged through one compressed air outlet (D), so that the first pipe body and the second pipe body of the second ice forming part are formed so that compressed air is discharged through one compressed air outlet (D). Ice particles or moisture mixed with moisture discharged from the two pipes are discharged through one compressed air outlet.
As the third valve (3) is disposed at the compressed air inlet (C), the third a port (3a) of the third valve is directly connected to the compressed air inlet, and the third valve (3b) port (3b) is directly connected to the compressed air inlet. communicates with the 5a port (5a) of the fifth valve (5), and the 3c port (3c) of the third valve (3) communicates with the 6a port (6a) of the sixth valve (6),
As the fourth valve (4) is disposed at the compressed air outlet (D), the 4th valve (4a) is directly connected to the compressed air outlet, and the 4th valve (4b) of the fourth valve (4) is directly connected to the compressed air outlet. communicates with the 7a port (7a) of the 7th valve (7), and the 4c port (4c) of the 4th valve (4) communicates with the 8a port (8a) of the 8th valve (8), Provided with a passage through which the compressed air is supplied to the first pipe body and the second pipe body,
When moisture is removed from a gas sample containing moisture through the first pipe body (110a), compressed air is supplied to the second pipe body (110b) to remove grains formed inside the second pipe body, and at this time, the third valve Port 3b, port 6b of valve 6, port 8c of valve 8, and port 4b of valve 4 are turned off, ports 3a and 3c of valve 3, and ports 6a and 6c of valve 6. port, ports 8b and 8a of the 8th valve, ports 4c and 4a of the 4th valve are turned on, and the compressed air supplied from the compressed air inlet (C) flows through ports 3a and 3 of the third valve. After communicating with port 3c and ports 6a and 6c of valve 6, ice particles or moisture are removed while passing through the second pipe body (110b), and ports 8b and 8a of valve 8 and ports 8 and 6 of valve 4 are connected. It is discharged to the compressed air outlet (D) through ports 4c and 4a, and at this time, the second pipe body (110b) is controlled to be maintained at an image level.
When moisture is removed from a gas sample containing moisture through the second pipe body (110b), compressed air is supplied to the first pipe body (110a) to remove grains formed inside the first pipe body, and at this time, the third valve The 3c port, the 5b port of the 5th valve, the 7c port of the 7th valve, and the 4c port of the 4th valve are turned off, the 3a and 3b ports of the 3rd valve, and the 5a and 5c ports of the 5th valve. port, ports 7b and 8a of the 7th valve, and ports 4b and 4a of the 4th valve are turned on, and the compressed air supplied from the compressed air inlet (C) flows through ports 3a and 3 of the third valve. After communicating with the 3b port and the 5a and 5c ports of the 5th valve, ice particles or moisture are removed while passing through the first pipe body (110a), and the 7b and 8a ports of the 7th valve and the 4th valve are connected. A device for removing moisture from a gas sample, characterized in that it is discharged to the compressed air outlet (D) through ports 4b and 4a, and at this time, the first pipe body (110a) is controlled to be maintained at an image level. delete According to clause 6,
A plate 120 surrounding the pipe body is provided, and the temperature controller 130 is attached to the plate to control the temperature inside the pipe body by changing the temperature of the plate to below or above zero. At this time, the material of the pipe body is glass or A device for removing moisture from a gas sample, characterized in that it is made of stainless steel. delete delete delete delete delete According to clause 8,
As the fifth valve 5 is disposed between the 1b port (1b) of the first valve and the first pipe inlet (110a1) of the first pipe body (110a), the 1b port (1b) of the first valve is connected to the 5b port (5b) of the 5th valve (5), and the 5c port (5c) of the 5th valve (5) is connected to the first pipe inlet (110a1),
As the 6th valve 6 is disposed between the 1c port (1c) of the first valve and the first pipe inlet (110b1) of the second pipe body (110b), the 1c port (1c) of the first valve is connected to the 6b port (6b) of the 6th valve (6), and the 6c port (6c) of the 6th valve (6) is connected to the second pipe inlet (110b1),
As the seventh valve 7 is disposed between the first pipe outlet (110a2) of the first pipe body (110a) and the 2b inlet (2b) of the second valve, the first pipe outlet (110a2) is It is connected to the 7b port (7b) of the 7th valve, and the 7c port (7c) of the 7th valve 7 is connected to the 2b port (2b) of the second valve,
As the eighth valve 8 is disposed between the second pipe outlet (110b2) of the second pipe body (110b) and the second c port (2c) of the second valve, the second pipe outlet (110b2) is It is connected to the 8b port (8b) of the 8th valve, and the 8c port (8c) of the 8th valve (8) is connected to the 2c port (2c) of the second valve.
A moisture removal device for a gas sample, characterized in that it has a passage through which the compressed air is supplied to the first pipe body and the second pipe body. delete According to clause 14,
When a gas sample containing moisture is supplied to the first pipe 110a and the moisture is removed, the 1c port of the first valve, the 5a port of the 5th valve, the 7th port of the 7th valve, and the 2c port of the 2nd valve The port is turned off, ports 1a and 1b of the first valve, ports 5b and 5c of the 5th valve, ports 7b and 7c of the 7th valve, and ports 2a and 2 of the second valve. District 2b is on
The gas sample containing moisture supplied from the gas sample inlet (A) passes through ports 1a and 1b of the first valve, then passes through ports 5b and 5c of the fifth valve, and then passes through the first pipe ( Moisture is removed while passing through 110a), passes again through ports 7b and 7c of the 7th valve, and is discharged to the gas sample outlet (B) through ports 2b and 2a of the second valve. A moisture removal device for a gas sample, characterized in that the first pipe body (110a) is maintained at a temperature below zero.