KR20220063024A - Apparatus and method for extracting and measuring impurities on compressed air including twocyclones - Google Patents

Abstract

The present invention relates to a device including a double cyclone device, which is provided to collect impurities of compressed air and measure the amount and state of the impurities. In particular, the present invention comprises a compressed air outlet connected in a forward direction to a rapid expansion space of a distal end circling flow path, wherein a circling flow path collision section is installed around an outlet entry route, so as to separate contained impurities after the cyclone wind collides thereagainst after having passed through the distal end circling flow path, and compressed air formed by the backflow and vortex may be discharged through the outlet. Therefore, the compressed air outlet may be provided to be connected in the forward direction which is identical to the air advancing direction of the distal end circling flow path. Accordingly, the structure of a device for collecting and measuring impurities by using a double cyclone device may be miniaturized and significantly simplified, thereby facilitating great ease in application on site.

Description

Impurity collecting and measuring device using a double cyclone device {Apparatus and method for extracting and measuring impurities on compressed air including twocyclones}

The present invention relates to a device (hereinafter also referred to as “impurity capture and measurement device”) for collecting impurities in compressed air including a double cyclone device and measuring the state such as the amount of the impurities. More specifically, a cyclone wind (or “swivel wind”) that has passed through the end turning passage by providing a compressed air outlet connected in the forward direction with the rapid expansion space of the end turning passage, but installing a turning passage collision zone around the outlet entrance that is connected to the outlet. ”) to separate the impurity contained therein and to discharge the compressed air formed by the countercurrent and vortex to the outlet. By doing so, it is possible to have a compressed air outlet that is connected in the same forward direction as the air travel direction of the end swirl flow path. it becomes much easier

The present invention is a product designed to measure and feed back or manage the quality of compressed air often used in industrial fields such as food factories in real time, thereby maintaining the quality of the product ultimately produced by the company at a high level and also minimizing the potential for defects. am.

Proper quality of compressed air is important to its users. If contaminant-laden compressed air comes into contact with the final product, the cost of rejecting it can become unacceptably high. For example, compressed air is used for washing and drying empty bottles and filling beverages in the process of producing beverages. At this time, if foreign substances are mixed, fatal problems such as mold growth in the distribution process may occur.

The most common contaminant found in compressed air is moisture in the compressed air. In the present invention, compressed air generally compresses the atmosphere, and the air in the atmosphere always contains moisture in the form of water vapor. A small amount of moisture contained in this compressed air may cause problems in many industrial processes. Examples include high maintenance costs, shortened service life, poor tool performance, increased defect rates in spray painting and plastic injection processes, increased leaks, disturbances in control systems and instruments, shortened service life due to corrosion, and high installation costs.

Another impurity in compressed air is oil. The amount of oil in compressed air depends on a number of factors, including the type, design, age and conditions of the equipment.

Also, microorganisms that may be contained in compressed air may be raised as other impurities. More than 80% of the particles polluting compressed air are less than 2 μm in size, so they can easily pass through the inlet filter of the air compressor. may proliferate.

In particular, in the food industry, the HACCP regulation of compressed air was only recently enacted. Until now, the compressed air that is directly/indirectly sprayed on food has been managed by the producers according to their own standards, but only recently In order to comply with the HACCP regulations for compressed air, the issue of measuring the state of the compressed air currently in use has arisen.

Until now, measuring devices that have been mainly used as a means of measuring compressed air quality in the food industry include a dew point meter, a particle counter, and an oil mist meter. However, each piece of equipment was expensive and required a lot of maintenance, and professionally trained personnel were required to handle it.

As a representative product, there is the S600 compressed air purity analyzer produced by SUTO of Germany.

More specifically, the price point is about 30 million won per unit, and it must be operated for more than 10 hours to obtain stable results. In addition, in order to analyze the output data, professional training is required, and since calibration is required every year to maintain the measurement precision, the cost and time burden are considerable.

Therefore, as the industry judges that the use of the above product is practically impossible, it is urgent to develop an innovative product to replace it.

Patent Application No. 10-2018-0169459 (Application date: 2018.12.26.)

In the present invention, while replacing existing compressed air analyzers such as the S600 compressed air purity analyzer, the price is remarkably low, the results can be obtained in real time, and it can be operated in any polluted situation. The goal is to develop an impurity trapping and measuring device that is strong against the environment, that is, an impurity trapping and measuring device using a double cyclone device. In addition, since the apparatus for collecting and measuring impurities using the dual cyclone device of the present invention also presents the output data after conclusive analysis, a separate professional training can be minimized to analyze the result value.

In addition, it is also important in the present invention to develop an impurity collecting and measuring device using a double cyclone device to easily satisfy the HACCP regulations of compressed air in the recently enacted food industry.

In addition, the present invention goes one step further and uses a dual cyclone device that can directly or indirectly intervene in the quality of compressed air based on the result as well as measure the state of compressed air, that is, properly remove impurities. I wanted to develop a device.

In addition, the present invention further provides a double cyclone device that can be connected with parts that can properly control the necessary parts of the entire system so that the quality of compressed air can be automatically maintained at a certain level by connecting the measurement results through communication in the long term. The impurity collection and measurement device used was developed.

In order to achieve the object of the present invention as described above and perform the characteristic functions of the present invention to be described later, the features of the present invention are as follows.

The present invention relates to a device for collecting impurities in compressed air including a double cyclone device and measuring the state such as the amount of the impurities. More specifically, it has a compressed air outlet connected in the forward direction to the rapid expansion space of the end swirl flow path, but installs a swirl flow path collision zone around the outlet entrance that is connected to the exhaust port. It is characterized in that the compressed air formed by the countercurrent and the vortex is discharged through the outlet. By doing so, it is possible to provide a compressed air outlet that is connected in the same forward direction as the air travel direction of the end swirl flow path. also much easier.

As shown in FIG. 1, the most characteristic structure of the present invention is that the introduced compressed air is formed as a cyclone wind while passing through the generators 210 and 300 of at least two stages, undergoes two impurity separation processes, The point is that compressed air proceeds through the outlet 560 connected in the forward direction with the air moving direction of 540). In particular, among these, the swirl flow passage collision zone 440 can be mentioned as a specially created configuration for “compressed air proceeds through the outlet connected in the forward direction with the air travel direction of the end swirl passage”, which is located around the exhaust inlet 550. installed.

The compressed air that has passed through the end generator 300 becomes a cyclone wind and passes through the end swirl flow path 540 and proceeds along the end swirl flow path whose diameter becomes narrower as it goes down to the bottom. It expands in the expansion area 541 and then collides with the wall and the bottom surface of the swirl flow path collision zone 440 formed around the discharge inlet due to the nature of the swirling wind. In this case, the progressing compressed air forms a countercurrent and separates the impurity it contains while accompanying a significant portion of the vortex. Of course, the impurities separated by the cyclone wind in some of the end turning passages may come down to the turning passage collision zone 440 along the wall.

After the compressed air collides with the wall and the bottom surface of the turning passage collision zone 440 , it changes direction again and goes out to the exhaust port 560 through the discharge inlet.

In the present invention, while replacing existing compressed air analyzers such as the S600 compressed air purity analyzer, the price is remarkably low, the results can be obtained in real time, and it can be operated in any polluted situation. The goal is to develop an impurity trapping and measuring device that is strong against the environment, that is, an impurity trapping and measuring device using a double cyclone device.

In addition, since the apparatus for collecting and measuring impurities using the dual cyclone device of the present invention also presents the output data after conclusive analysis, a separate professional training to analyze the result can also be minimized.

In addition, it is also important in the present invention to develop an impurity collecting and measuring device using a double cyclone device to easily satisfy the HACCP regulations of compressed air in the recently enacted food industry.

In addition, the present invention goes one step further and uses a dual cyclone device that can directly or indirectly intervene in the quality of compressed air based on the result as well as measure the state of compressed air, that is, properly remove impurities. device was developed.

The present invention has developed a device that not only serves as a measuring device but also actively manages the quality of compressed air through an impurity outlet, a measuring device, and an impurity external storage tank having a means for discharging continuous or intermittent impurities related thereto.

In addition, the present invention furthermore connects the measurement results through communication so that the quality of compressed air can be automatically maintained at a certain level, and impurities are collected using a dual cyclone device that can be connected with parts that can properly control the necessary parts of the entire system and developing a measuring device.

1 is a cross-sectional view of an impurity trapping and measuring apparatus 1000 of the present invention.
2 is a cross-sectional view and a perspective view of an initial generator generating cylinder 1020, which is one of the internal components of the impurity trapping and measuring apparatus of the present invention.
3 is a cross-sectional view and a perspective view of an end turning passage tube 1010, which is one of the internal components of the impurity collection and measurement device of the present invention.
4 shows an embodiment of the impurity collection and measurement apparatus 1000. An impurity outlet 140 capable of discharging impurities filled in the cover scale 170 and the impurity collecting units 410 and 430 in a transparent outer cylinder. ) is a perspective view including
5 and 6 are examples in which the filler is filled so that the impurity collecting part can know how much impurities are collected, and each silica gel and cobalt chloride are filled.
7 is a perspective view showing an embodiment of the impurity collection and measurement apparatus 1000 in which the position of the impurity outlet 130 for discharging the impurities filled in the impurity collecting units 410 and 430 is different.
8 and 9 show one embodiment of the impurity collection and measurement apparatus 1000, and the impurities filled in the impurity collecting units 410 and 430 are discharged through the impurity outlet pipe 132 to a separate impurity external storage container ( 133) is a perspective view measured together.
10 shows an embodiment of a method of coupling the impurity collection and measurement apparatus 1000 in which the impurity collection and measurement apparatus 1000 is not coupled to the main compressed air pipe 800 but to a separate compressed air bypass pipe 810. is a perspective view.
11 is a cross-sectional view and a perspective view of an embodiment of the bypass connection pipe 820 .
12 is a cross-sectional view of an impurity collecting and measuring device having no first impurity collecting unit therein.
13 and 14 show an impurity measurement and communication module 900 separately installed outside, in two embodiments, wireless and wired, with a control unit inside, and the measurement result of the impurity collection and measurement device 1000 and the measurement that can be received from the outside. The state of the pressure air may be controlled based on the result, or the measurement result of the impurity collection and measurement apparatus 1000 may be transmitted to a control unit installed outside another, and the state of the pressure air may be controlled according to the instruction of the control unit.

In the present invention, the meanings of “impurity collection and measurement device” and “impurity collection and measurement device using a double cyclone device” are distinguished.

“Impurity collection and measurement device” refers to the device shown in FIG. 1, and refers to a case where the impurity outlet is also attached. On the other hand, “a device for collecting and measuring impurities using a double cyclone device” is an embodiment of the present invention, and it is a name that refers to all embodiments of the invention pursued by the present invention as well as “a device for collecting and measuring impurities”. In other words, a device having an impurity outlet pipe and an external impurity storage tank is not an “impurity collection and measurement device”, but “a device for collecting and measuring impurities using a double cyclone device”.

The present invention relates to a device for collecting impurities in compressed air including a double cyclone device and measuring the state such as the amount of the impurities. More specifically, it has a compressed air outlet connected in the forward direction with the rapid expansion space of the end swirl flow path, but installs a swirl flow path collision zone around the outlet entrance road, so that the cyclone wind that has passed through the end swing flow path collides to separate impurities and counter-flow It is characterized in that the compressed air formed by the vortex is discharged to the outlet. By doing so, it is possible to provide a compressed air outlet that is connected in the same forward direction as the air travel direction of the end swirl flow path. also much easier.

Specific structural or functional descriptions presented in the embodiments of the present invention are only exemplified for the purpose of explaining the embodiments according to the concept of the present invention, and the embodiments according to the concept of the present invention may be implemented in various forms. In addition, it should not be construed as being limited to the embodiments described herein, and it should be understood to include all modifications, equivalents and substitutes included in the spirit and scope of the present invention.

Meanwhile, in the present invention, terms such as first and/or second may be used to describe various components, but the components are not limited to the terms. The above terms are used only for the purpose of distinguishing one component from other components, for example, within the scope not departing from the scope of the rights according to the concept of the present invention, the first component may be named as the second component, Similarly, the second component may also be referred to as a first component.

When a component is referred to as being “connected” or “connected” to another component, it should be understood that it may be directly connected or connected to the other component, but other components may exist in between. something to do. On the other hand, when it is said that a certain element is "directly connected" or "directly contacted" with another element, it should be understood that no other element is present in the middle. Other expressions for describing the relationship between elements, that is, expressions such as "between" and "immediately between" or "adjacent to" and "directly adjacent to", should be interpreted similarly.

Like reference numerals refer to like elements throughout. Meanwhile, the terminology used herein is for the purpose of describing the embodiments and is not intended to limit the present invention. In this specification, the singular form also includes the plural form unless otherwise specified in the phrase. As used herein, “comprises” and/or “comprising” means that the stated component, step, operation and/or element is the presence of one or more other components, steps, operations and/or elements. or addition is not excluded.

Hereinafter, the inventions described herein will be described in detail on the basis of the accompanying drawings.

1 is an embodiment in which the core concept of the present invention is shown.

As shown in FIG. 1, the most characteristic structure of the present invention is that the introduced compressed air is formed as a cyclone wind while passing through the generators 210 and 300 of at least two stages, undergoes two impurity separation processes, The point is that compressed air proceeds through the outlet 560 connected in the forward direction with the air moving direction of 540). In particular, among these, the swirl flow path collision zone 440 can be mentioned as a specially created configuration for “compressed air proceeds through the outlet connected in the forward direction with the air travel direction of the end swirl flow path”, which is a discharge inlet (550) connected to the outlet. ) is installed around the

The compressed air that has passed through the end generator 300 becomes a cyclone wind and passes through the end swirl flow path 540 and proceeds along the end swirl flow path whose diameter becomes narrower as it goes down to the bottom. It expands in the expansion area 541 and then collides with the wall and the bottom surface of the swirl flow path collision zone 440 formed around the discharge inlet due to the nature of the swirling wind. In this case, the progressing compressed air forms a countercurrent and separates the impurity it contains while accompanying a significant portion of the vortex. Of course, the impurities separated by the cyclone wind in some of the end turning passages may come down to the turning passage collision zone 440 along the wall.

After the compressed air collides with the wall and the bottom surface of the turning passage collision zone 440 , it changes direction again and goes out to the exhaust port 560 through the discharge inlet.

The turning passage collision zone 440 is installed at the lower end of the end turning passage and has a closed-down structure including a discharge inlet wall 650 and a collision partition wall 660 located on an extension line of the outlet. The shape of the turning flow passage collision zone 440 is sufficient as long as it is possible to accommodate the compressed air coming down through the end turning flow passage rapid expansion region 541 of the end turning flow passage and form a counterflow after the collision. It can be designed in various ways. . It can be said that it is more preferable for the swirling wind to come down and collide with the outside in the swirl flow path collision zone 440 as possible and to flow back inward. At this time, it is preferable that the diameter of the discharge inlet is equal to or smaller than the diameter of the point at which the rapid expansion region 541 of the end turning passage of the end turning passage starts. However, the diameter of the outlet or the height of the wall of the outlet can be appropriately selected by those skilled in the art as needed in the process of implementing the present invention.

In addition, the content of the present invention will be described with reference to FIG. 1 .

Compressed air is introduced through the compressed air inlet (110). The introduced compressed air is moved toward the initial generator 210 by the compressed air distribution jaw 600 . At this time, it is somewhat helpful to have the compressed air distribution jaw 600 , but it is not necessary. Compressed air that has passed through the initial generator 210 is changed into a swirling wind (or has the same meaning as a “cyclone wind”) and passes through the entry swirling passage 510. At this time, the relatively large impurities contained in the compressed air are cyclone wind. separated due to the centrifugal force of Here, the impurities usually include organic substances such as moisture, oil grains, microorganisms, and the like. Most of them are water, but the type of impurity tends to be determined by the path through which the compressed air is introduced.

In this way, the compressed air that has passed through the entry vortex passage 510 reaches the entry vortex passage expansion region 511, and at this time, it rapidly hits the floor and flows back into the next entry passage. Some impurities in the compressed air are separated. The impurities thus separated are collected in the first impurity collecting unit 410 through the first impurity outlet 710 under the influence of the centrifugal force of the swirling wind.

The impurities collected in the swirl flow path collision zone 440 described above are also collected to the terminal impurities collecting unit 430 through the terminal impurities outlet 720 .

Usually, the first impurity collecting part 410 and the terminal impurity collecting part 430 are separated by a collecting part dividing wall 670. If necessary, the collecting part dividing wall 670 is removed and the two collecting parts are one area can also be done with

The impurity collecting part is usually connected to the outside through the impurity outlets 130 and 140 . In some cases, as shown in FIG. 7 , there may be an embodiment in which impurities are discharged from time to time by manually placing an impurity discharge button 131 as needed. This will be described in more detail later.

2 shows an embodiment of an initial generator generating cylinder 1020 that forms an initial generator 210 in contact with the air inlet cover 100 inside the combined air inlet cover 100 and the outer cylinder 610. It is a drawing.

FIG. 3 is an initial generator generating cylinder 1020, an outer cylinder 610, and an end turning passage tube 1010 which is combined with the air exhaust cover 120 to form an end turning passage and the like.

4 is an embodiment of the present invention, in which all or at least part of the outer wall of the first impurity collecting part 410 or the outer cylindrical part of the distal impurity collecting part 430 is transparent, and a cover scale 170 is formed on the outside. It is an impurity collecting and measuring device using a double cyclone device that is made to easily identify the state of collecting impurities from the outside. 4 is also another embodiment in which the position of the impurity outlet 140 is different.

5 and 6 are the types belonging to FIG. 4, and in the case of FIG. 5, the first impurity collecting part is filled with silica gel, and in the case of FIG. 6, the first impurity collecting part is filled with cobalt chloride. Of course, these are merely examples, and those skilled in the art may of course select or combine various fillers capable of distinguishing the amount and type of impurities as needed.

8 and 9 are an impurity collecting and measuring device using a dual cyclone device that connects an impurity outlet pipe 132 to an impurity outlet to discharge impurities, classify them in a separate device, and then operate according to various uses.

In this case, the present invention can be used for various purposes.

First, it can be used as a device that continuously removes impurities such as moisture. For example, if the impurities in the external impurity storage tank 133 are filled over a certain level, impurities are continuously removed in such a way that a certain portion of the impurities are discharged outside in a completely separated state so as not to affect the internal pressure of the impurity collecting and measuring device. may be able to let it out.

In addition, it is possible to actively manage the quality of compressed air as well as play a role as a measuring device through the impurity outlet, the measuring device, and the impurity external storage bin equipped with a means for discharging continuous or intermittent impurities related thereto.

In addition, by further developing the external impurity storage tank and connecting the measurement result through communication, it can be connected to the parts that can properly control the necessary parts of the entire system so that the quality of the compressed air can be automatically maintained at a certain level. It is possible to create an impurity collection and measurement device using a dual cyclone device that becomes the control center or transmits the measurement contents to the control center and actively manages compressed air in real time in cooperation with, for example, a compressor.

This is to cite several examples, and various types of impurities such as moisture can be continuously removed or an external impurity storage container 133 that contributes to management can be developed.

Second, as a device for measuring the content of impurities such as moisture and the type of impurities in compressed air regularly or irregularly, the device for collecting and measuring impurities using the dual cyclone device of the present invention can be utilized. For example, by connecting the impurity outlet pipe 132 to the impurity outlet, the impurities are discharged and sorted into a separate device, and then a device for distinguishing the types of impurities or measuring their amounts is added to the external impurity storage tank 133 to be mounted. will be able Thus, it will be possible to solve the problem in various forms, such as sending the measured state as data to the comprehensive management system using the communication network and activating the impurity removal function of the compressor, filter, or the device of the present invention when there is an abnormality.

Third, it is possible to combine the function of a device that removes impurities such as moisture and a device that measures the content of impurities such as moisture and the type of impurities in compressed air. This will expand the concept of the external impurity storage tank 133 to perform the above two functions at the same time. In addition, it can be said that it is also within the scope of a person skilled in the art to transmit the current status continuously or at regular intervals or through communication when there is a risk of a problem or a problem occurs.

10 is another embodiment of the present invention by installing a separate bypass pipe from the compressed air pipe 800, the impurity collection and measuring apparatus 1000 of the present invention is installed. The impurity trapping and measuring apparatus of FIGS. 8 and 9 can of course be applied. In FIG. 10 , various functions may be provided to the bypass pipe connection unit 820 . If the time for measuring impurity collection is determined, the internal structure of the bypass pipe connection part 820 will be designed to bypass compressed air only by a predetermined amount for a predetermined time and for a predetermined time.

If the impurity collection and measurement device 1000 installed in FIG. 10 functions as a device for removing impurities such as moisture and as a device for measuring the content of impurities such as moisture and types of impurities in compressed air, the bypass pipe The internal structure of the connection part 820 is a little more complicated, so it can receive various information depending on the state of the compressed air fed back from the impurity collection and measurement device 1000. something to do.

100: air inlet cover 110: compressed air inlet
120: air exhaust cover 130, 140: impurities outlet
131: impurity discharge button 132: impurity outlet pipe
133: impurities external storage container 151: euro pipe connection means 1
152: euro pipe connection means 2 170: cover scale
210: initial generator
300: end generator 310: end generator wing
410: first impurity collecting unit 430: terminal impurity collecting unit
440: turning flow path collision zone
510: entry turning passageway 520: terminal entry passageway
540: terminal turning flow passage 541: terminal turning passage rapid expansion area
550: outlet inlet 560: outlet
600: compressed air distribution jaw 610: outer cylinder
620: collecting partial wall 630: separating inner wall
650: exhaust inlet wall 660: impact partition wall
670: collecting part partition wall
710: first impurity outlet 720: terminal impurity outlet
800: compressed air pipe 810: compressed air bypass pipe
820: bypass pipe connection part 830: bypass control valve
840: bypass control blade 900: impurity measurement and communication module
910: wire cable 920: impurity instrument panel
930 ; Instrument menu change button 940: Reset button
950: rigid discharge button 960: power button
970: wireless module
1000: impurity collection and measurement device 1010: end turning flow passage
1020: Initial generator generating cylinder
a: silica gel b: cobalt chloride

Claims (14)

compressed air inlet;
initial generator;
entry turning path;
terminal entry passage;
end generator;
end turning passage;
turning passage collision zone;
exhaust inlet;
outlet;
a first impurity outlet communicating with the entry turning passage; and
Including an end impurity outlet communicating with the turning passage collision zone,
As the compressed air passes through the entry swirl passage, impurities are first separated, and the separated impurities flow out through the first impurity outlet, and then collide with the swirl passage collision zone to separate impurities, and then the separated impurities are Impurity collecting and measuring device using a dual cyclone device, characterized in that it flows out through the end impurity outlet, and thereafter, the compressed air is discharged through an outlet connected in the same forward direction as the air moving direction in the end swirl passage. The method according to claim 1,
Compressed air introduced through the compressed air inlet passes through the initial generator and turns into a cyclone wind, passes through the entry vortex flow path, primarily separates impurities, passes through the terminal entry flow path, and is a strong cyclone wind through the terminal generator After passing through the end turning passage, it collides with the turning passage collision zone to separate impurities, and then discharges it to the outlet,
The entry turning passage includes an entry turning passage expansion area at the bottom,
The apparatus for collecting and measuring impurities using a dual cyclone device, characterized in that the terminal turning passage includes a rapid expansion area at the bottom of the end turning passage connected to the turning passage collision zone. The method according to any one of claims 1 to 2,
a first impurity collecting unit communicating with the entry turning passage through the first impurity outlet;
The impurity collecting and measuring device using a double cyclone device, characterized in that it includes a terminal impurity collecting part communicating with the turning passage collision zone as the terminal impurity outlet. 4. The method according to claim 3,
Impurity collecting and measuring apparatus using a double cyclone device, characterized in that the first impurity collecting unit and the terminal impurity collecting unit are formed in one room. The method according to any one of claims 1 to 2,
Impurity collecting and measuring apparatus using a dual cyclone device, characterized in that the impurities flowing out to the first impurity outlet and the impurities flowing out to the terminal impurity outlet are discharged to the outside of the impurity collecting and measuring device through the impurity outlet. 4. The method according to claim 3,
The impurity collecting and measuring device using a double cyclone device, characterized in that the outer cylinder wall of the impurity collecting unit is transparent, so that the type and amount of impurities in the impurity collecting unit can be measured. 7. The method of claim 6,
Impurity collection using a dual cyclone device, characterized in that partly filled with silica gel or cobalt chloride in the impurity collecting unit and marking a scale on the wall of the corresponding outer cylinder of the impurity collecting unit to facilitate the measurement of the type and amount of impurities measuring device. 6. The method of claim 5,
Impurity collection and measurement device using a double cyclone device, characterized in that the impurities are manually discharged. 6. The method of claim 5,
Impurity collection and measurement apparatus using a dual cyclone device, characterized in that an impurity outlet pipe is connected to the impurity outlet, and the impurity outlet pipe is connected to an external impurity storage container, so that the collection, measurement, and discharge of the impurities occur in the impurity external storage container . 6. The method of claim 5,
Impurity collecting and measuring device using a double cyclone device, characterized in that it further comprises a function of discharging the impurities related to the quality of the compressed air. 10. The method of claim 9,
Impurity collecting and measuring device using a double cyclone device, characterized in that it further comprises a function of discharging the impurities related to the quality of the compressed air. compressed air inlet;
initial generator;
entry turning path;
terminal entry passage;
end generator;
end turning passage;
turning passage collision zone;
exhaust inlet;
outlet;
a first impurity outlet communicating with the entry turning passage; and
Including an end impurity outlet communicating with the turning passage collision zone,
As the compressed air passes through the entry swirl passage, impurities are first separated, and the separated impurities flow out through the first impurity outlet, and then collide with the swirl passage collision zone to separate impurities, and then the separated impurities are The impurity collection and measurement device using a double cyclone device is connected to the compressed air pipe by a bypass pipe connection part, which flows out through the end impurity outlet and then the compressed air is discharged through the outlet connected in the same forward direction as the air flow direction in the end swirl passage. Impurity collection and measurement device system using a double cyclone device, characterized in that it is formed on the compressed air bypass pipe. 13. The method of claim 12,
The bypass pipe connection part is an impurity collection and measurement system using a double cyclone device, characterized in that it is designed to bypass a predetermined amount of compressed air for a predetermined time according to a scheduled time for impurity collection measurement. 13. The method of claim 12,
The bypass pipe connection unit can receive various information according to the state of the compressed air fed back from the impurity collection and measurement device using the double cyclone device, and is designed to accommodate the indicated case. Impurity collection and measurement system using

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