KR102483425B1 - Apparatus and method for extracting and measuring impurities on compressed air including twocyclones - Google Patents

Abstract

The present invention relates to a device for collecting impurities in compressed air including a double cyclone device and measuring conditions such as the amount of the impurities. More specifically, a compressed air outlet connected in the forward direction to the rapid expansion space of the end swirling passage is provided, but a swirling passage collision zone is installed around the outlet entrance to separate impurities contained by the collision of the cyclone wind passing through the terminal swirling passage and reverse flow. It is characterized in that the compressed air formed by the vortex and discharged to the discharge port. By doing so, it is possible to provide a compressed air outlet connected in the same forward direction as the air flow direction of the terminal swirl flow path, thereby dramatically simplifying the structure of the impurity collection and measuring device using the double cyclone device, such as miniaturization, as well as field applicability it becomes much easier

Description

Impurity collection 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 collection and measurement device") that collects impurities from compressed air and measures conditions such as the amount of the impurities, including a double cyclone device. More specifically, a compressed air outlet connected to the rapid expansion space of the terminal swirl passage in a forward direction is provided, but a swirl passage collision zone is installed around the outlet access road connected to the discharge port, so that the cyclone wind (or “swirling wind”) passing through the terminal swirl passage It is characterized in that the impurity is separated and the compressed air formed by countercurrent and vortex is discharged through the outlet. By doing so, it is possible to have a compressed air outlet connected in the same forward direction as the air flow direction of the terminal swirl flow path, thereby dramatically simplifying the structure of the impurity collection and measuring device using the double cyclone device, such as miniaturization, as well as field applicability it becomes much easier

The present invention measures and feedbacks or manages the quality of compressed air, which is widely used in industries such as food factories, in real time, thereby maintaining the quality of products ultimately produced by companies at a high level and minimizing the possibility of defects. to be.

Compressed air of suitable quality is important to the users who use it. When contaminant-laden compressed air comes into contact with the final product, the cost of handling the defect can become unaffordable. For example, in the process of producing beverages, compressed air is used for washing and drying empty bottles, filling beverages, etc. At this time, if foreign substances are mixed in, fatal problems such as mold growth may occur in the distribution process.

One of the most common contaminants found in compressed air is moisture in 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. Due to the slight moisture contained in such compressed air, many industrial process problems may occur. Examples include high maintenance costs, reduced service life, poor tool performance, increased reject rates in spray painting and plastic injection processes, increased water leakage, disturbance of control systems and instruments, reduced 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 of equipment, its design, age and conditions.

In addition, microorganisms that may be contained in compressed air may present other impurities. More than 80% of the particles that contaminate compressed air are less than 2 μm in size, so they can easily pass through the inlet filter of the air compressor, and the particles diffuse throughout the pipe system, mixing with moisture and oil residues, pipe sediments, etc., forming microorganisms. may proliferate.

Especially in the food industry, the HACCP regulation for compressed air was enacted only recently. Until now, compressed air that is directly/indirectly sprayed on food has been managed by producers on their own standards, but only recently In order to meet the HACCP regulations for compressed air, the issue of measurement, that is, showing the condition of the compressed air currently in use, has emerged.

Until now, the measurement devices used mainly as a means of measuring the quality of compressed air in the food industry include dew point meters, particle counters, and oil mist meters. However, each piece of equipment was not only expensive, but also costly to maintain, and required specialized trained personnel to handle it.

A representative product is the S600 compressed air purity analyzer produced by Germany's SUTO.

To explain more, the price range is about 30 million won per unit, and it must be operated for more than 10 hours to obtain stable results, and because it uses expensive and precise sensors, it is paradoxically very vulnerable to polluted environments. In addition, professional training is required to analyze the output data, and since annual calibration is required to maintain measurement accuracy, cost and time burden are significant.

Therefore, since the industry judges that the use of the above products is virtually impossible, it is urgent to develop innovative products to replace them.

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

In the present invention, while replacing the existing compressed air analyzer such as the S600 compressed air purity analyzer, the price is remarkably low, the result can be obtained in real time, and it can be operated in any contaminated situation. It is intended to develop an impurity collection and measurement device that is strong in the environment, that is, an impurity collection and measurement device using a double cyclone device. In addition, since the impurity collecting and measuring device using the double cyclone device of the present invention presents the output data after analysis in conclusion, separate professional training can be minimized to analyze the result value.

In addition, it is also important in the present invention to develop a device for collecting and measuring impurities using a double cyclone device so that it can easily satisfy the recently established HACCP (HACCP) regulations of compressed air in the food industry.

In addition, the present invention goes one step further and measures the state of compressed air as well as collects and measures impurities using a double cyclone device that can directly or indirectly intervene in the quality of compressed air based on the result, in other words, can properly remove impurities I wanted to develop a device.

In addition, the present invention further provides a dual cyclone device that can be connected to a part 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 measured results through communication in the long run. It developed an impurity collection and measurement device using

In order to achieve the object of the present invention as described above and to perform the characteristic functions of the present invention described later, the characteristics 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 conditions such as the amount of the impurities. More specifically, a compressed air outlet connected to the rapid expansion space of the terminal swirl passage in the forward direction is provided, but a swirl passage collision zone is installed around the outlet entry road connected to the outlet to remove impurities contained by the collision of the cyclone wind passing through the terminal swirl passage. It is characterized in that the compressed air formed by the reverse flow and the vortex is discharged through the discharge port. By doing so, it is possible to have a compressed air outlet connected in the same forward direction as the air flow direction of the terminal swirl flow path, thereby dramatically simplifying the structure of the impurity collection and measuring device using a double cyclone device, such as miniaturization, as well as field application also becomes much easier.

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

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

The compressed air that collides with the wall and the floor of the swirling path collision zone 440 is reversed and then changed direction again to go out to the discharge port 560 through the discharge inlet.

In the present invention, while replacing the existing compressed air analyzer such as the S600 compressed air purity analyzer, the price is remarkably low, the result can be obtained in real time, and it can be operated in any contaminated situation. It is intended to develop an impurity collection and measurement device that is strong in the environment, that is, an impurity collection and measurement device using a double cyclone device.

In addition, since the impurity collecting and measuring device using the double cyclone device of the present invention presents the output data after analysis in conclusion, separate professional training can be minimized to analyze the result value.

In addition, it is also important in the present invention to develop a device for collecting and measuring impurities using a double cyclone device so that it can easily satisfy the recently established HACCP (HACCP) regulations of compressed air in the food industry.

In addition, the present invention goes one step further and measures the state of compressed air as well as collects and measures impurities using a double cyclone device that can directly or indirectly intervene in the quality of compressed air based on the result, in other words, can properly remove impurities device was developed.

The present invention has developed a device that actively manages the quality of compressed air as well as a role as a measuring device through an impurity external storage container equipped with an impurity outlet, a measuring device, and a means for discharging continuous or intermittent impurities associated therewith.

In addition, the present invention goes further and collects impurities using a double cyclone device that can be connected to a part 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 measured results through communication and developed a measuring device.

1 is a cross-sectional view of an impurity collection measuring device 1000 according to 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 parts of the impurity collection and measuring device of the present invention.
3 is a cross-sectional view and a perspective view of an end swirling passage 1010, which is one of the internal parts of the impurity collection and measuring device of the present invention.
4 shows an embodiment of the impurity collecting and measuring device 1000, and the impurity discharge port 140 capable of discharging the impurities charged in the cover scale 170 and the impurity collecting parts 410 and 430 in the transparent outer cylinder. ) is a perspective view including.
5 and 6 are examples in which the impurity collecting unit is filled with fillers so that the amount of impurities collected in the impurity collecting unit is known, and each silica gel and cobalt chloride are filled.
FIG. 7 is a perspective view showing an embodiment of the impurity collection and measuring device 1000 in which the position of the impurity outlet 130 for discharging impurities charged in the impurity collecting units 410 and 430 is different.
8 and 9 show an embodiment of the impurity collection and measuring device 1000, in which the impurities charged in the impurity collection units 410 and 430 are discharged through the impurity outlet pipe 132 to separate the 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 device 1000 in which the impurity collection and measurement device 1000 is not coupled to the main compressed air pipe 800 and is coupled to a separate compressed air bypass pipe 810 It is a perspective view.
11 is a cross-sectional view and a perspective view showing one embodiment of a bypass connection pipe 820.
12 is a cross-sectional view of the impurity collecting and measuring device without the first impurity collecting unit therein.
13 and 14 are two embodiments of wireless and wired impurities measuring and communication modules 900 separately installed outside, with a control unit inside, measurement results of the impurity collection measuring device 1000 and measurements that can be received from the outside The state of the pressurized air may be controlled based on the result, or the state of the pressurized air may be controlled by sending the measurement result of the impurity collection measuring device 1000 to a control unit installed outside, and according to the instructions of the control unit.

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

"Impurity collection measurement device" refers to the device shown in Figure 1, and refers to the case where the impurity outlet is attached. On the other hand, “impurity collection and measurement device using a double cyclone device” is an embodiment of the present invention, and is a name referring to “impurity collection and measurement device” as well as all embodiments of the invention pursued by the present invention. In other words, the device with the impurity outflow pipe and the external storage container for impurities is not an “impurity collection and measurement device”, but “an impurity collection and measurement device 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 conditions such as the amount of the impurities. More specifically, a compressed air outlet connected in the forward direction to the rapid expansion space of the end swirling passage is provided, but a swirling passage collision zone is installed around the outlet entrance to separate impurities contained by the collision of the cyclone wind passing through the terminal swirling passage and reverse flow. It is characterized in that the compressed air formed by the vortex and discharged to the discharge port. By doing so, it is possible to have a compressed air outlet connected in the same forward direction as the air flow direction of the terminal swirl flow path, thereby dramatically simplifying the structure of the impurity collection and measuring device using a double cyclone device, such as miniaturization, as well as field application also becomes much easier.

Specific structural or functional descriptions presented in the embodiments of the present invention are merely exemplified for the purpose of explaining embodiments according to the concept of the present invention, and 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 in this specification, and should be understood to include all modifications, equivalents, or 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 above terms. The above terms are used only for the purpose of distinguishing one component from other components, for example, within a range not departing from the scope of rights according to the concept of the present invention, a first component may be referred to as a second component, Similarly, the second component may also be referred to as the first component.

It should be understood that when an element is referred to as being "connected" or "connected" to another element, it may be directly connected or connected to the other element, but other elements may exist in the middle. something to do. On the other hand, when an element is referred to as “directly connected” or “directly in contact” with another element, it should be understood that no other element exists in the middle. Other expressions used to describe the relationship between elements, such as "between" and "directly between" or "adjacent to" and "directly adjacent to" should be interpreted similarly.

Like reference numbers indicate like elements throughout the specification. Meanwhile, terms used in this specification are for describing embodiments and are not intended to limit the present invention. In this specification, singular forms also include plural forms unless specifically stated otherwise in a phrase. As used herein, “comprises” and/or “comprising” means the presence of one or more other components, steps, operations, and/or elements in which a stated component, step, operation, and/or element is present. or do not rule out additions.

Hereinafter, the inventions described in this specification will be described in detail based on the accompanying drawings.

1 is an embodiment showing the core concept of the present invention.

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

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

The compressed air that collides with the wall and the floor of the swirling path collision zone 440 is reversed and then changed direction again to go out to the discharge port 560 through the discharge inlet.

The swirl passage collision zone 440 is installed at the lower end of the end swirl passage and has a bottom closed structure including a discharge inlet wall 650 and a collision partition wall 660 on the extension line of the discharge port. The shape of the swirl passage collision area 440 can be designed in various ways as long as it can accommodate compressed air coming down through the end swirl passage rapid expansion area 541 of the end swirl passage as much as possible and form a reverse flow after collision. . It can be said that it is more preferable that the swirling wind descends to the outside within the possible swirling passage collision area 440, collides with it, and flows backward inward. At this time, the diameter of the discharge inlet is preferably equal to or smaller than the diameter of the point at which the rapid expansion region 541 of the terminal swirl passage begins. However, the diameter of the discharge inlet or the height of the discharge inlet wall can be selected and implemented by those skilled in the art as needed in the process of implementing the present invention.

In addition, the contents 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. In this case, the existence of the compressed air distribution jaw 600 is somewhat helpful, but not necessarily. The compressed air that has passed through the initial generator 210 is changed into swirling wind (or has the same meaning as “cyclone wind”) and passes through the entry swirling passage 510. are separated due to the centrifugal force of Here, impurities include organic substances such as moisture, oil grains, and microorganisms. Among them, a large part is moisture, but the type of impurities tends to be determined by the route through which the compressed air is introduced.

Compressed air passing through the entry turning passage 510 reaches the entry turning passage expansion region 511, and at this time, it rapidly hits the bottom and flows backward to enter the next entry passage. Some impurities in the compressed air are separated. The separated impurities are gathered into the first impurity collector 410 through the first impurity outlet 710 under the influence of the centrifugal force of the swirling wind.

Impurities collected in the swirling path collision zone 440 described above are also collected in the terminal impurity collector 430 through the terminal impurity outlet 720.

Normally, the first impurity collecting unit 410 and the terminal impurity collecting unit 430 are separated by a collecting unit dividing wall 670. If necessary, the collecting unit dividing wall 670 is removed and the two collecting units are combined into one area. can also be done with

The impurity collecting unit 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 manually discharged from time to time as needed by placing an impurity discharge button 131 . This will be described in more detail later.

FIG. 2 shows an embodiment of an initial generator generating cylinder 1020 forming an initial generator 210 by contacting the air inlet cover 100 inside the air inlet cover 100 and the outer cylinder 610 coupled thereto. it is a drawing

FIG. 3 is an end swirl passage cylinder 1010 combining the initial generator generating cylinder 1020, the outer cylinder 610, and the air discharge cover 120 to form an end swirl passage.

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

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

8 and 9 are impurity collecting and measuring devices using a double cyclone device that connects the impurity outlet to the impurity outlet, discharges impurities, classifies them into separate devices, and then operates them in various ways according to use.

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, when impurities in the external impurity storage container 133 fill up to a certain level or more, a certain portion of impurities are continuously discharged to the outside in a completely separated state so as not to affect the internal pressure of the impurity collecting and measuring device. will be able to release it.

In addition, it is possible to actively manage the quality of compressed air as well as a role as a measuring device through an impurity outlet, a measuring device, and an impurity external storage container equipped with a means for discharging impurities continuously or intermittently associated therewith.

In addition, by further developing the external storage container for impurities and connecting the measured results through communication, the necessary parts of the entire system can be connected to parts that can properly control the quality of the compressed air 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 double cyclone device that becomes a control center or transmits measurement contents to the control center and actively manages compressed air in real time in cooperation with a compressor, for example.

As a few examples, it is possible to develop an impurity external storage container 133 that continuously removes or manages impurities such as moisture in various forms.

Second, as a device for regularly or irregularly measuring the degree of content of impurities such as moisture in compressed air and the type of impurities, the impurity collecting and measuring device using the double cyclone device of the present invention can be utilized. For example, by connecting the impurity outlet pipe 132 to the impurity discharge port, the impurities are discharged and classified into a separate device, and then a device for distinguishing the type of impurities or measuring the amount thereof is added to the impurity external storage container 133 and installed. You will be able to. 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 device of the present invention if there is an abnormality.

Third, it is possible to produce a product that functions as a device that removes impurities such as moisture and functions as a device that measures the degree of content of impurities such as moisture in compressed air and the type of impurities. This may be accomplished by expanding the concept of the external impurity storage container 133 to simultaneously perform the above two functions. In addition, it can be said that it is within the scope of course for those skilled in the art to transmit the current state continuously or at regular intervals, or when there is a possibility of a problem or a problem occurs through communication.

10 is another embodiment of the present invention, in which the impurity collection measuring device 1000 of the present invention is installed by installing a separate bypass pipe from the compressed air pipe 800. The impurity collection measuring device of FIGS. 8 and 9 can be applied as a matter of course. In FIG. 10 , various functions may be assigned to the bypass pipe connection unit 820 . If the time for the impurity collection measurement is determined, the internal structure of the bypass pipe connection 820 will naturally be designed to bypass the compressed air for a predetermined amount at a predetermined time and for a predetermined time.

If the impurity collection measurement device 1000 installed in FIG. 10 has a function as a device for removing impurities such as moisture and a function as a device for measuring the degree of content of impurities such as moisture in compressed air and the type of impurities, the bypass pipe The internal structure of the connection part 820 is more complicated so that it can receive various information according to the state of the compressed air fed back from the impurity collection measuring device 1000 and must be designed to accommodate various cases indicated according to the case. something to do.

100: air inlet cover 110: compressed air inlet
120: air discharge cover 130, 140: impurity 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 wings
410: first impurity collecting unit 430: terminal impurity collecting unit
440: turning passage collision zone
510: entry turning passage 520: end entry passage
540: end turning passage 541: end turning passage rapid expansion area
550: discharge inlet 560: discharge port
600: compressed air distribution jaw 610: outer tube
620: collection part separation wall 630: separation inner wall
650: discharge inlet wall 660: collision partition wall
670: collection part partition wall
710: first impurity outlet 720: terminal impurity outlet
800: compressed air pipe 810: compressed air bypass pipe
820: bypass pipe connection 830: bypass control valve
840: bypass control wing 900: impurity measurement and communication module
910: wire cable 920: impurity instrument panel
930; Instrument menu conversion button 940: initialization button
950: rigid body ejection button 960: power button
970: wireless module
1000: impurity collection measuring device 1010: terminal turning passage
1020: initial generator generation pain
a: Silky gel b: Cobalt chloride

Claims (14)

compressed air inlet;
initial generator;
entry turn route;
end entry passage;
terminal generator;
end turning passage;
turning passage collision zone;
discharge inlet;
outlet;
a first impurity outlet communicating with the entry turning passage; and
Including a terminal impurity outlet communicating with the swirling passage collision zone,
Compressed air first separates impurities as it passes through the entry swirl passage, 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 An impurity collecting and measuring device using a double cyclone device, characterized in that the compressed air is discharged through the terminal impurity outlet, and then the compressed air is discharged to the outlet connected in the same forward direction as the air traveling direction in the terminal swirling passage. The method of claim 1,
The compressed air introduced through the compressed air inlet passes through the initial generator, is changed into cyclone wind, and passes through the entry swirl passage to primarily separate impurities, and passes through the end entry passage to pass through the terminal generator as strong cyclone wind. After passing through the terminal swirling passage, it hits the swirling passage collision zone to separate impurities and discharge them to the discharge port,
The entry turning passage includes an entry turning passage expansion area at the bottom,
Impurity collecting and measuring device using a double cyclone device, characterized in that the terminal swirling passage includes a terminal swirling passage rapid expansion region connected to the swirling passage collision zone at a lower end. According to any one of claims 1 and 2,
A first impurity collecting unit communicating with the entry turning passage through the first impurity outlet; and
An impurity collecting and measuring device using a double cyclone device, characterized in that it comprises a terminal impurity collecting part communicating with the swirling passage collision zone as the terminal impurity outlet. The method of claim 3,
Impurity collecting and measuring device using a double cyclone device, characterized in that the first impurity collecting part and the terminal impurity collecting part are formed as one room. According to any one of claims 1 and 2,
An impurity collecting and measuring device using a double cyclone device, characterized in that the impurities flowing out through the first impurity outlet and the impurities flowing out through the terminal impurity outlet are discharged out of the impurity collecting and measuring device through the impurity outlet. The method of claim 3,
At least one of the first impurity collecting part and the terminal impurity collecting part has a transparent outer wall, so that the type and amount of impurities can be measured. The method of claim 6,
An impurity collecting and measuring device using a double cyclone device, characterized in that the first impurity collecting part is partially filled with silica gel or cobalt chloride and a scale is displayed on the wall of the outer cylinder to facilitate measurement of the type and amount of impurities. The method of claim 5,
Impurity collection and measurement device using a double cyclone device, characterized in that for manually discharging impurities. The method of claim 5,
An impurity collecting and measuring device using a double cyclone device, characterized in that an impurity outlet pipe is connected to the impurity outlet and the impurity outlet pipe is connected to an impurity external storage container so that the impurity is collected, measured, and discharged in the impurity external storage container. . 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. 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 turn route;
end entry passage;
terminal generator;
end turning passage;
turning passage collision zone;
discharge inlet;
outlet;
a first impurity outlet communicating with the entry turning passage; and
Including a terminal impurity outlet communicating with the swirling passage collision zone,
Compressed air first separates impurities as it passes through the entry swirl passage, 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 An impurity collecting and measuring device using a double cyclone device, which flows out through the terminal impurity outlet, and then the compressed air is discharged to the outlet connected in the same forward direction as the air flow direction in the terminal swirling passage, is connected to the compressed air pipe through a bypass pipe connection. Impurity collecting and measuring device system using a double cyclone device, characterized in that formed on the compressed air bypass pipe. The method of claim 12,
The impurity collection and measurement device system using a double cyclone device, characterized in that the bypass pipe connection is designed to bypass a predetermined amount of compressed air for a predetermined time in accordance with the scheduled impurity collection measurement time. The method of claim 12,
The bypass pipe connection unit can receive various information according to the state of compressed air fed back from the impurity collecting and measuring device using the double cyclone device, and is designed to accommodate the case of being instructed. Impurity collection and measuring device system using

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