KR102622945B1 - Cleanig apparatus using CO2 - Google Patents

Abstract

The present invention is a carbon dioxide spray cleaning device that cleans the cleaning object by spraying dry ice, which is cooled carbon dioxide, to remove foreign substances such as organic substances, acids, hydrocarbons, metal thin films, particulates, impurities, etc. attached to the surface of various cleaning objects. It's about.
To this end, the present invention is a carbon dioxide injection cleaning device that removes foreign substances by spraying carbon dioxide on an object to be cleaned, and provides a composite device that receives carbon dioxide and air and sprays the air into a plurality of gas injection holes formed on the surface facing the object. A fluid injection assembly is disposed inside the composite fluid injection assembly, and the carbon dioxide supplied to the composite fluid injection assembly flows into one end, and the carbon dioxide is injected into the other end, and the other end is located at the center of the gas injection hole. It includes a carbon dioxide injection nozzle disposed, a carbon dioxide supply part that supplies the carbon dioxide to the composite fluid injection assembly, and an air supply part that supplies the air to the composite fluid injection assembly, wherein the outer surface of the other end of the carbon dioxide injection nozzle is formed with the gas. It is disposed to be spaced apart from the inner surface of the injection hole, and the air is injected from an area between the outer surface of the other end of the carbon dioxide injection nozzle and the inner surface of the gas injection hole.

Description

Carbon dioxide spray cleaning device {Cleanig apparatus using CO2}

The present invention relates to a carbon dioxide spray cleaning device, and more specifically, to remove foreign substances such as organic substances, acids, hydrocarbons, metal thin films, particulates, impurities, etc. attached to the surfaces of various cleaning objects, using dry ice, which is cooled carbon dioxide. It relates to a carbon dioxide spray cleaning device that sprays and cleans the object to be cleaned.

Typically, a carbon dioxide scrubber is a device that removes foreign substances by spraying dry ice particles, which are cooled carbon dioxide that is harmless to industrial facilities and the environment, at high speed.

At this time, by adjusting the amount and speed of the sprayed dry ice, devices made of various materials such as ceramics, synthetic resins, rare metals, fiber glass, rubber, plastics, steel, and electronic parts, die casting mold cleaning, reactor interior cleaning, and tires Like cleaning molds, foreign substances attached to the surface of various products can be removed.

In addition, dry ice particles sublimate into a harmless gas as soon as they impact the surface, removing only foreign substances without causing any damage to the surface being cleaned, and leaving no secondary contaminants or moisture, so they can be used in food processing, confectionery, rubber, plastic, etc. As it is widely used in all industrial fields such as pharmaceuticals, automobile manufacturing, aircraft maintenance, aerospace, electrical and electronics, semiconductor industry, petrochemical, steel, and printing, there is a demand for more high-performance dry ice cleaners.

In addition, the cleaning characteristics of the dry ice spray cleaning device include the amount of dry ice particles generated, the degree of cohesion of dry ice particles, the efficiency of the Venturi effect, the location of frost generation, and the amount of frost generated. These cleaning characteristics can be optimized by the flexibility of the nozzle structure.

However, existing cleaning devices have the problem of complicated assembly because nozzles are joined by welding or joining.

In addition, the existing cleaning device includes a plurality of nozzles and supplies liquefied carbon dioxide so that dry ice can be sprayed from each nozzle. At this time, the carbon dioxide supply part is coupled to each nozzle and is configured to supply carbon dioxide. This problem becomes more complicated.

To solve this problem, when a single carbon dioxide supply unit supplies carbon dioxide to a plurality of nozzles, it is difficult to supply a constant amount of carbon dioxide to each nozzle.

Republic of Korea Patent Publication No. 10-2054770 (Title of invention: Dry ice scrubber, Announcement date: December 11, 2019)

Accordingly, the present invention expands the inner diameter of the injection area where carbon dioxide is injected from the carbon dioxide injection nozzle into three stages, so that carbon dioxide can adiabatically expand into three stages to stably generate and inject dry ice, and the carbon dioxide supply passage is formed in a T-shape. The purpose is to provide a carbon dioxide injection cleaning device that improves injection conditions by uniformly distributing carbon dioxide to each carbon dioxide injection nozzle.

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

In order to solve the above-described problem, the present invention is a carbon dioxide injection cleaning device that removes foreign substances by spraying carbon dioxide on a cleaning object, and receives carbon dioxide and air through a plurality of gas injection holes formed on the surface facing the cleaning object. A composite fluid injection assembly that injects air is disposed inside the composite fluid injection assembly, and the carbon dioxide supplied to the composite fluid injection assembly flows into one end, and the carbon dioxide is injected into the other end. It includes a carbon dioxide injection nozzle disposed at the center of the gas injection hole, a carbon dioxide supply unit for supplying the carbon dioxide to the composite fluid injection assembly, and an air supply unit for supplying the air to the composite fluid injection assembly, wherein the other end of the carbon dioxide injection nozzle The outer surface is disposed to be spaced apart from the inner surface of the gas injection hole, and the air is injected from the area between the outer surface of the other end of the carbon dioxide injection nozzle and the inner surface of the gas injection hole. .

Here, the composite fluid injection assembly has a carbon dioxide supply passage through which the carbon dioxide moves to one end of the carbon dioxide injection nozzle, and the carbon dioxide supply passage may be formed in a T shape.

Additionally, the inner diameter of the other end of the carbon dioxide injection nozzle expands toward the end, so that the carbon dioxide injected from the carbon dioxide injection nozzle can adiabatically expand.

The effects of the carbon dioxide injection cleaning device according to the present invention are as follows.

First, since the single composite fluid injection assembly simultaneously sprays air and dry ice onto the cleaning object, the configuration of separate nozzles for spraying air and dry ice is omitted, which has the advantage of simplifying the device configuration.

Second, the carbon dioxide supply flow path is formed in a T shape, which has the advantage of improving injection conditions by uniformly distributing carbon dioxide to each carbon dioxide injection nozzle.

Third, the inner diameter of the injection area where carbon dioxide is injected from the carbon dioxide injection nozzle is expanded to three stages, which has the advantage of allowing carbon dioxide to adiabatically expand into three stages to stably generate and inject dry ice.

Fourth, there is the advantage of convenient assembly because the composite fluid injection assembly and the carbon dioxide injection nozzle are combined through tap processing.

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

Figure 1 is a perspective view of a carbon dioxide injection cleaning device according to the present invention.
Figure 2 is a cross-sectional view taken along the direction AA' of Figure 1 of the carbon dioxide spray cleaning device according to the present invention.
Figure 3 is a cross-sectional view taken along the BB' direction of Figure 1 of the carbon dioxide spray cleaning device according to the present invention.
Figure 4 is a diagram showing a carbon dioxide supply block of the carbon dioxide spray cleaning device according to the present invention.
Figure 5 is a diagram showing a carbon dioxide distribution block of the carbon dioxide spray cleaning device according to the present invention.
Figure 6 is a diagram showing the air supply block of the carbon dioxide injection cleaning device according to the present invention.
Figure 7 is a diagram showing the first carbon dioxide injection nozzle holding block of the carbon dioxide injection cleaning device according to the present invention.
Figure 8 is a diagram showing a second carbon dioxide injection nozzle holding block of the carbon dioxide injection cleaning device according to the present invention.
Figure 9 is a diagram showing the gas injection block of the carbon dioxide injection cleaning device according to the present invention.
10 to 12 are diagrams showing the carbon dioxide injection nozzle of the carbon dioxide injection cleaning device according to the present invention.

The advantages and features of the present invention and methods for achieving them will become clear by referring to the embodiments described in detail below along with the accompanying drawings. However, the present invention is not limited to the embodiments disclosed below and may be implemented in various different forms. The present embodiments are merely provided to ensure that the disclosure of the present invention is complete and to be understood by those skilled in the art. It is provided to fully inform those who have the scope of the invention, and the present invention is only defined by the scope of the claims. Like reference numerals refer to like elements throughout the specification.

The terms used herein are used to describe specific embodiments and are not intended to limit the invention. As used herein, the singular forms include the plural forms unless the context clearly indicates otherwise. In addition, throughout this specification, when a part “includes” a certain element, this means that it may further include other elements unless specifically stated to the contrary.

When a component is said to be “connected” or “connected” to another component, it is understood that it may be directly connected to or connected to that other component, but that other components may exist in between. It should be. On the other hand, when a component is said to be “directly connected” or “directly connected” to another component, it should be understood that there are no other components in between. Other expressions to describe relationships between components should be interpreted similarly.

All terms, including technical or scientific terms, used in this specification have the same meaning as generally understood by those skilled in the art to which the present invention pertains, unless otherwise defined. Terms defined in commonly used dictionaries should be interpreted as having a meaning consistent with the meaning in the context of the related technology, and unless clearly defined in this specification, should not be interpreted in an idealized or overly formal sense. No.

As used herein, terms such as one side, other side, top, bottom, upper surface, lower surface, top, bottom, etc. are used to distinguish relative positions of components.

1 is a perspective view of a carbon dioxide spray cleaning device according to the present invention. The carbon dioxide spray cleaning device according to the present invention sprays cooled carbon dioxide, that is, dry ice, on the cleaning object to remove organic matter attached to the surface of the cleaning object, It is a device that removes foreign substances such as acids, hydrocarbons, metal thin films, particles, and impurities. Referring to FIG. 1, the carbon dioxide injection cleaning device according to the present invention includes a composite fluid injection assembly (1000), a carbon dioxide injection nozzle (2000), and a carbon dioxide supply unit. It includes (3000) and an air supply unit (4000), which will be described with reference to FIGS. 1 and 2 to 12 as follows.

FIG. 2 is a cross-sectional view of the carbon dioxide injection cleaning device in the direction A-A' of FIG. 1 according to the present invention, and FIG. 3 is a cross-sectional view of the carbon dioxide injection cleaning device in the B-B' direction of FIG. 1 according to the present invention. As shown in FIGS. 1 to 3, the composite fluid injection assembly 1000 receives carbon dioxide (CO2) and air from the carbon dioxide supply unit 3000 and the air supply unit 4000 and faces the cleaning object. The air is injected through a plurality of gas injection holes 1622 formed on the viewing surface, and specifically, the composite fluid injection assembly 1000 includes a carbon dioxide supply block 1100, a carbon dioxide distribution block 1200, and an air supply block 1300. , a first carbon dioxide injection nozzle holding block 1400, a second carbon dioxide injection nozzle holding block 1500, and a gas injection block 1600.

Figure 4 is a perspective view (a) and a cross-sectional view (b) of the carbon dioxide supply block 1100 of the carbon dioxide injection cleaning device according to the present invention.

Referring to FIG. 4, the carbon dioxide supply block 1100 is connected to the carbon dioxide supply unit 3000 to receive liquid carbon dioxide inside, and is formed in the shape of a square block, inside which is a carbon dioxide supply channel through which the carbon dioxide moves. (1110) is formed.

Additionally, one end of the carbon dioxide supply block 1100 is connected to the carbon dioxide supply unit 3000, so that carbon dioxide moves from the carbon dioxide supply unit 3000 to the carbon dioxide supply passage 1110.

The carbon dioxide supply passage 1110 is formed in a T shape. Specifically, the carbon dioxide supply passage 1110 includes a first carbon dioxide supply passage 1111 and a second carbon dioxide supply passage 1112.

The first carbon dioxide supply passage 1111 is formed inside the carbon dioxide supply block 1100 in the longitudinal direction of the carbon dioxide supply block 1100 and is formed across one side to the other side of the carbon dioxide supply block 1100. , The cross section is circular but is formed as a straight flow path.

One end of the first carbon dioxide supply passage 1111 is coupled to the carbon dioxide supply unit 3000 and receives carbon dioxide from the carbon dioxide supply unit 3000, so that the carbon dioxide reaches the other end of the first carbon dioxide supply passage 1111.

The second carbon dioxide supply passage 1112 is connected to the first carbon dioxide supply passage 1111 and is composed of a plurality of second carbon dioxide supply passages 1112.

That is, the second carbon dioxide supply passage 1112 extends from the lower surface of the first carbon dioxide supply passage 1111 toward the bottom of the carbon dioxide supply block 1100, and specifically, the first carbon dioxide supply passage 1111 ) is formed to extend vertically from the lower surface of the , one end is connected to the side of the first carbon dioxide supply passage 1111, and the other end is formed to open through the lower surface of the first carbon dioxide supply block 1100. .

The carbon dioxide supply passage 1110 includes the first carbon dioxide supply passage 1111 and the second carbon dioxide supply passage 1112, and the first carbon dioxide supply passage 1111 and the second carbon dioxide supply passage 1112 is arranged vertically, and the carbon dioxide supply passage 1110 is formed in a T-shape, thereby generating a vortex within the carbon dioxide supply passage 1110 and uniformly distributing carbon dioxide to each carbon dioxide injection nozzle 2000, which will be described later. By doing so, the injection conditions of carbon dioxide can be improved.

Figure 5 is a diagram illustrating the carbon dioxide distribution block 1200 of the carbon dioxide injection cleaning device according to the present invention. The carbon dioxide distribution block 1200 is disposed below the carbon dioxide supply block 1100 and supplies the carbon dioxide supply block 1100. ) and distributes the carbon dioxide delivered from the carbon dioxide supply passage 1110 into a plurality of parts.

Specifically, the carbon dioxide distribution block 1200 includes a first carbon dioxide distribution block 1210 and a second carbon dioxide distribution block 1220.

The first carbon dioxide distribution block 1210 is disposed below the carbon dioxide supply block 1100 and is coupled to the carbon dioxide supply block 1100. The first carbon dioxide distribution block 1210 is formed in the shape of a square block, A first carbon dioxide distribution passage 1211 is formed in an area corresponding to the area where the second carbon dioxide supply passage 1112 is formed.

That is, carbon dioxide moves from the second carbon dioxide supply passage 1112 to the first carbon dioxide distribution passage 1211, and at this time, an O-ring, etc. is provided between the lower part of the carbon dioxide supply block 1100 and the upper part of the carbon dioxide supply block 1100. A sealing member is interposed to prevent carbon dioxide moving from the second carbon dioxide supply passage 1112 to the first carbon dioxide distribution passage 1211 from leaking between the carbon dioxide supply block 1100 and the carbon dioxide supply block 1100. .

The second carbon dioxide distribution block 1220 is disposed below the first carbon dioxide distribution block 1210 and is coupled to the first carbon dioxide distribution block 1210, and the second carbon dioxide distribution block 1220 has a square block shape. A carbon dioxide diffusion passage 1221 and a second carbon dioxide distribution passage 1222 are formed.

The carbon dioxide diffusion passage 1221 is formed on the upper surface of the second carbon dioxide distribution block 1220, that is, on the surface facing the lower part of the first carbon dioxide distribution block 1210. The upper surface is formed to be open, and as shown in (c) of FIG. 5, is formed in a channel shape extending in the longitudinal direction of the second carbon dioxide distribution block 1220, and the first carbon dioxide distribution channel 1211 Carbon dioxide moving from is allowed to diffuse into the carbon dioxide diffusion passage 1221.

At this time, the thickness of the carbon dioxide diffusion passage 1221 is preferably the same as the diameter of the first carbon dioxide distribution passage 1211.

The second carbon dioxide distribution passage 1222 is connected to the carbon dioxide diffusion passage 1221, and a plurality of second carbon dioxide distribution passages 1222 are formed, the number of which corresponds to the number of carbon dioxide injection nozzles 2000, which will be described later.

In addition, the second carbon dioxide distribution passage 1222 extends from the lower surface of the carbon dioxide diffusion passage 1221 toward the bottom of the second carbon dioxide distribution block 1220, and the second carbon dioxide distribution passage 1222 is It is formed to extend vertically from the lower surface of the carbon dioxide diffusion passage 1221, with one end connected to the lower surface of the carbon dioxide diffusion passage 1221 and the other end being formed to be open to the lower surface of the second carbon dioxide distribution block 1220. do.

Specifically, the second carbon dioxide distribution passage 1222 includes a 2-1 carbon dioxide distribution passage 1222a and a 2-2 carbon dioxide distribution passage 1222b.

The 2-1 carbon dioxide distribution passage 1222a extends from the lower surface of the carbon dioxide diffusion passage 1221 toward the lower part of the second carbon dioxide distribution block 1220, and at this time, the 2-1 carbon dioxide distribution passage ( The diameter of 1222a) is the same as the outer diameter of the first carbon dioxide flow pipe 2200, which will be described later, and the first carbon dioxide flow pipe 2200 is inserted and coupled to the 2-1 carbon dioxide distribution passage 1222a, the description of which is This will be described later.

The 2-2 carbon dioxide distribution passage 1222b extends from the lower surface of the 2-1 carbon dioxide distribution passage 1222a toward the lower portion of the second carbon dioxide distribution block 1220, thereby forming the second carbon dioxide distribution block 1220. ) is formed so that the lower surface is open, and at this time, the diameter of the 2-2 carbon dioxide distribution channel (1222b) is formed to be larger than the diameter of the 2-1 carbon dioxide distribution channel (1222a), and the 2-2 carbon dioxide distribution channel (1222b) is formed to be larger than the diameter of the 2-1 carbon dioxide distribution channel (1222a). The first carbon dioxide flow pipe 2200 is inserted and coupled to the flow path 1222b, which will be described later.

Figure 6 is a diagram showing the air supply block 1300 of the carbon dioxide injection cleaning device according to the present invention. The air supply block 1300 is formed in the shape of a square block and is disposed at the lower part of the carbon dioxide distribution block 1200. It is combined with the carbon dioxide distribution block 1200, and a first flow pipe insertion hole 1310, a first air movement passage 1320, and an air supply space 1330 are formed.

The first flow pipe insertion hole 1310 is located on the upper surface of the air supply block 1300 corresponding to the area where the 2-2 carbon dioxide distribution passage 1222b is formed. is formed in the corresponding number, and at this time, the diameter of the first flow pipe insertion hole 1310 is the same as the outer diameter of the first carbon dioxide flow pipe 2200, which will be described later, and the first flow pipe insertion hole 1310 is provided with the first carbon dioxide flow pipe 2200. The carbon dioxide flow pipe 2200 is inserted and coupled, which will be described later.

The first air movement passage 1320 is formed on the side of the air supply block 1300 and is connected to the air supply unit 4000, and flows air from the air supply unit 4000 to the first air movement passage 1320. moves.

The air supply space 1330 is formed in the shape of a flow path formed in the longitudinal direction of the air supply block 1300 at the lower part of the air supply block 1300, and its upper surface is connected to the first flow pipe insertion hole 1310. The side is connected to the first air movement passage 1320, and air moves from the first air movement passage 1320 to the air supply space 1330.

At this time, the air supply space 1330 is opened toward the bottom of the air supply block 1300.

Figure 7 is a diagram showing the first carbon dioxide injection nozzle holding block 1400 of the carbon dioxide injection cleaning device according to the present invention. The first carbon dioxide injection nozzle holding block 1400 is formed in the shape of a square block, and the air supply It is disposed at the lower part of the block 1300 and combined with the air supply block 1300, and a second flow pipe insertion hole 1410 and a second air movement passage 1420 are formed.

The second flow pipe insertion holes 1410 are formed in plural numbers corresponding to the area corresponding to the vertical direction of the first flow pipe insertion hole 1310 formed in the air supply block 1300, and the first carbon dioxide injection The first carbon dioxide flow pipe 2200 is formed to penetrate the nozzle holding block 1400, and at this time, the diameter of the second flow pipe insertion hole 1410 is the same as the outer diameter of the first carbon dioxide flow pipe 2200, which will be described later, The first carbon dioxide flow pipe 2200 is inserted and coupled to the second flow pipe insertion hole 1410, which will be described later.

The second air movement passage 1420 is formed on the side surface of the second flow pipe insertion hole 1410 of the first carbon dioxide injection nozzle holding block 1400, and moves air from the first air movement passage 1320. allows it to move downward through the second air movement passage 1420.

At this time, as shown in FIG. 7, the shape of the second air movement path 1420 has a length in the area between the plurality of second flow pipe insertion holes 1410 and on the side of the second flow pipe insertion hole 1410. It may be formed in a shape that extends long in the direction, but in addition, it may be formed in a shape that allows air moving from the first air movement passage 1320 to freely move downward through the second air movement passage 1420. It is replaceable.

Figure 8 is a diagram showing the second carbon dioxide injection nozzle holding block 1500 of the carbon dioxide injection cleaning device according to the present invention, wherein the second carbon dioxide injection nozzle holding block 1500 is the first carbon dioxide injection nozzle holding block 1400. ) and is coupled to the first carbon dioxide injection nozzle holding block 1400. Specifically, the second carbon dioxide injection nozzle holding block 1500 is the 2-1 carbon dioxide injection nozzle holding block 1510 and the second carbon dioxide injection nozzle holding block 1510. -2 Includes a carbon dioxide injection nozzle holding block (1520).

The 2-1 carbon dioxide injection nozzle holding block 1510 is formed in the shape of a square block, is disposed below the first carbon dioxide injection nozzle holding block 1400, and is coupled to the first carbon dioxide injection nozzle holding block 1400. A first holding pipe insertion hole 1511 and a third air movement passage 1512 are formed.

The first holding pipe insertion holes 1511 are formed in plural numbers corresponding to the area corresponding to the vertical direction of the second flow pipe insertion hole 1410 formed in the first carbon dioxide injection nozzle holding block 1400, The outer holding pipe 2100 is formed to penetrate the 2-1 carbon dioxide injection nozzle holding block 1510, and at this time, the diameter of the first holding pipe insertion hole 1511 is the outer holding pipe 2100, which will be described later. is the same as the outer diameter of , and the outer holding tube 2100 is inserted and coupled into the first holding tube insertion hole, which will be described later.

The third air movement passage 1512 is formed on the side surface of the first holding pipe insertion hole 1511 of the 2-1 carbon dioxide injection nozzle holding block 1510, and flows from the second air movement passage 1420. The moving air is allowed to move downward through the third air movement passage 1512.

At this time, the shape of the third air movement path 1512 may be formed as a shape extending longitudinally on the side of the plurality of first holding pipe inserts, as shown in FIG. It can be replaced with a shape that allows air moving from the second air movement passage 1420 to freely move downward through the third air movement passage 1512.

The 2-2 carbon dioxide injection nozzle holding block 1520 extends from the lower surface of the 2-1 carbon dioxide injection nozzle holding block 1510 and is formed in a U-shape, with an end of the 2-1 carbon dioxide injection nozzle holding block 1510. It is connected to the lower surface of the holding block (1510).

Specifically, the 2-2 carbon dioxide injection nozzle holding block 1520 includes a fixing part 1521 and a coupling part 1522.

The fixing part 1521 protrudes from the lower surface of the 2-1 carbon dioxide injection nozzle holding block 1510, and inserts the first holding tube disposed at both ends of the plurality of first holding tube insertion holes 1511. It protrudes from the side of the hole 1511 at a certain length. Of course, the fixing part 1521 may be formed of two pieces as described above, but as shown in FIG. 8, it may be composed of three pieces spaced apart at regular intervals, and the size of the carbon dioxide injection cleaning device according to the present invention And the number may be changed depending on the number of carbon dioxide injection nozzles 2000 that are combined.

The coupling part 1522 has one end and the other end coupled to the fixing part 1521 and is disposed parallel to the 2-1 carbon dioxide injection nozzle holding block 1510, and its thickness is equal to the thickness of the fixing part 1521. It is formed in the same manner, and the second holding pipe insertion hole 1522a and the third flow pipe insertion hole 1522b are formed in the coupling portion 1522.

The second holding tube insertion hole 1522a is formed in plural numbers corresponding to the area corresponding to the vertical direction of the first holding tube insertion hole 1511 formed in the 2-1 carbon dioxide injection nozzle holding block 1510. It is formed from the upper surface of the block portion to the center of the block portion so that the outer holding pipe 2100 penetrates the coupling portion 1522. At this time, the diameter of the second holding pipe insertion hole 1522a is as described later. It is the same as the outer diameter of the outer holding pipe 2100, and a description of this will be provided later.

The third flow pipe insertion hole 1522b is formed in plural numbers corresponding to the number of the second holding pipe insertion holes 1522a. Specifically, one end of the third flow pipe insertion hole 1522b is inserted into the second holding pipe insertion hole 1522b. It is connected to the lower part of the hole 1522a, and the other end is formed to open the lower surface of the coupling portion 1522.

At this time, the diameter of the third flow pipe insertion hole 1522b is the same as the outer diameter of the second carbon dioxide flow pipe 2300, and a description of this will be provided later.

Figure 9 is a diagram showing the gas injection block 1600 of the carbon dioxide injection cleaning device according to the present invention. The gas injection block 1600 is disposed below the second carbon dioxide injection nozzle holding block 1500, and 2 It is coupled to the carbon dioxide injection nozzle holding block 1500, and specifically, the gas injection block 1600 includes a coupling block 1610 and an injection block 1620.

The coupling block 1610 is formed in the shape of a square block, is disposed at the lower part of the second carbon dioxide injection nozzle holding block 1500, and is coupled to the second carbon dioxide injection nozzle holding block 1500, and holds the first gas in the center. A moving passage 1611 is formed, so that air moves through the first gas moving passage 1611, and the carbon dioxide injection nozzle 2000 passes through it.

The injection block 1620 protrudes from the lower part of the coupling block 1610 and is formed in a shape that surrounds the outer surface of the 2-2 carbon dioxide injection nozzle holding block 1520, and has the first gas movement inside. A second gas movement passage 1621 connected to the passage 1611 is formed, and air moves through the second gas movement passage 1621, and the carbon dioxide injection nozzle 2000 passes through it.

At this time, gas injection holes 1622 are formed on the lower surface of the injection block 1620 in a number corresponding to the number of carbon dioxide injection nozzles 2000, and the diameter of the gas injection holes 1622 is the second carbon dioxide flow pipe. It is formed wider than the outer diameter of (2300).

Here, the end of the second carbon dioxide flow pipe 2300 is disposed at the center of the gas injection hole 1622, and the outer surface of the second carbon dioxide flow pipe 2300 is consistent with the inner surface of the gas injection hole 1622. They are arranged to be spaced apart, and accordingly, the air of the second gas movement passage 1621 is injected from the area between the outer surface of the other end of the carbon dioxide injection nozzle 2000 and the inner surface of the gas injection hole 1622, The carbon dioxide is injected from the end of the second carbon dioxide flow pipe 2300, and a detailed description thereof will be provided later.

10 to 12 are diagrams showing the carbon dioxide injection nozzle 2000 of the carbon dioxide injection cleaning device according to the present invention. According to FIGS. 10 to 12, the carbon dioxide injection nozzle 2000 is the composite fluid injection assembly 1000. It is disposed on the inside, and the carbon dioxide supplied to the composite fluid injection assembly 1000 flows into one end, and the carbon dioxide is injected into the other end. Specifically, the carbon dioxide injection nozzle 2000 has an outer holding pipe 2100, It includes a first carbon dioxide flow pipe (2200), a second carbon dioxide flow pipe (2300), a first carbon dioxide holding pipe (2400), a second carbon dioxide holding pipe (2500), and a carbon dioxide compression pipe (2600).

The outer holding pipe 2100 holds the outside of the first carbon dioxide flow pipe 2200, the second carbon dioxide flow pipe 2300, and the carbon dioxide compression pipe 2600, and at the same time holds the composite fluid injection assembly 1000 and the first carbon dioxide flow pipe ( 2200), the second carbon dioxide flow pipe 2300, and the carbon dioxide compression pipe 2600 are combined.

The outer holding pipe 2100 is coupled to the second carbon dioxide injection nozzle holding block 1500, and specifically, one end of the outer holding pipe 2100 is formed on the 2-1 carbon dioxide injection nozzle holding block 1510. It is inserted into the first holding tube insertion hole 1511, and the other end of the outer holding tube 2100 is inserted into the second holding tube insertion hole 1522a of the coupling portion 1522.

At this time, the diameters of the first holding tube insertion hole 1511 and the second holding tube insertion hole 1522a are formed to be the same as the outer diameter of the outer holding tube 2100, as described above. ) Through a processing operation, the outer holding pipe 2100 is inserted and coupled into the first holding pipe insertion hole 1511 and the second holding pipe insertion hole 1522a.

A first flow pipe insertion portion 2110, a second flow pipe insertion portion 2120, and a compression pipe insertion portion 2130 are formed in the center of the outer holding pipe 2100.

The first flow pipe insertion portion 2110 is formed in the upper region of the center of the outer holding pipe 2100, and has a diameter equal to the outer diameter of the first carbon dioxide flow pipe 2200. The end area is inserted through a tap processing operation, and one end of the carbon dioxide compression pipe 2600 is inserted into the first flow pipe insertion portion 2110.

The second flow pipe insertion portion 2120 is formed in the lower region of the center of the outer holding pipe 2100, and has a diameter equal to the outer diameter of the second carbon dioxide flow pipe 2300. The end area is inserted through a tap (TAP) processing operation, and the other end of the carbon dioxide compression pipe 2600 is inserted into the second flow pipe insertion portion 2120.

The compression tube insertion part 2130 is formed in the central area of the center of the outer holding tube 2100, one end of which is connected to the first flow tube insertion part 2110, and the other end of which is connected to the second flow tube insertion part 2120. ) is connected to. At this time, the diameter of the compression tube insertion part 2130 is the same as the outer diameter of the carbon dioxide compression tube 2600, and the center of the carbon dioxide compression tube 2600 penetrates the compression tube insertion part 2130.

That is, the first flow pipe insertion portion 2110, the second flow pipe insertion portion 2120, and the compression pipe insertion portion 2130 are formed in the outer holding pipe 2100, and each has a first carbon dioxide flow pipe 2200. , the second carbon dioxide flow pipe 2300 and the carbon dioxide compression pipe 2600 are inserted while preventing the first carbon dioxide flow pipe 2200, the second carbon dioxide flow pipe 2300, and the carbon dioxide compression pipe 2600 from being separated by vibration or external force. Fix the position.

The first carbon dioxide flow pipe 2200 receives liquid carbon dioxide and moves it toward the carbon dioxide compression pipe 2600. Specifically, one end of the first carbon dioxide flow pipe 2200 is connected to the second carbon dioxide distribution block 1220. It is inserted into and coupled to the 2-1 carbon dioxide distribution passage (1222a) and the 2-2 carbon dioxide distribution passage (1222b) and the first flow pipe insertion hole (1310) formed in the air supply block (1300). The end portion is inserted and coupled to the inside of the first flow pipe insertion portion 2110 of the outer holding pipe 2100.

At this time, the liquid carbon dioxide delivered from the 2-1 carbon dioxide distribution passage (1222a) moves into the inner space of the first carbon dioxide flow pipe 2200, and the outer surface of the first carbon dioxide flow pipe 2200 and the second -2 A sealing means such as an O-ring for sealing and fixing is interposed between the carbon dioxide distribution passages 1222b to strengthen the coupling of the first carbon dioxide flow pipe 2200.

In addition, one end of the carbon dioxide compression pipe 2600 is inserted inside the other end of the first carbon dioxide flow pipe 2200, and carbon dioxide moving in the first carbon dioxide flow pipe 2200 moves to the carbon dioxide compression pipe 2600. By doing so, carbon dioxide is compressed in the carbon dioxide compression pipe 2600.

The first carbon dioxide holding pipe 2400 has a first compression pipe insertion hole 2410 formed in the center, and is disposed inside the other end of the first carbon dioxide flow pipe 2200, and the first carbon dioxide holding pipe 2400 The outer diameter of is the same as the inner diameter of the first carbon dioxide flow pipe 2200, and the inner diameter of the first carbon dioxide holding pipe 2400 is the same as the outer diameter of the carbon dioxide compression pipe 2600.

That is, the first carbon dioxide holding pipe 2400 is interposed between the first carbon dioxide flow pipe 2200 and the carbon dioxide compression pipe 2600 to secure the carbon dioxide compression pipe 2600 from the first carbon dioxide flow pipe 2200. do.

The second carbon dioxide holding pipe 2500 is inserted into the second flow pipe insertion part 2120, and specifically, the second carbon dioxide holding pipe 2500 includes the 2-1 carbon dioxide holding pipe 2510 and the 2-2 Includes a carbon dioxide holding tube (2520).

The 2-1 carbon dioxide holding pipe 2510 is inserted into the second flow pipe insertion portion 2120, and its outer diameter is formed to be the same as the outer diameter of the second flow pipe insertion portion 2120, and its inner diameter is the carbon dioxide compression pipe. It is formed to be the same as the inner diameter of 2600, and its length is shorter than the length of the other end of the carbon dioxide compression tube 2600 inserted into the second flow tube insertion part 2120.

The 2-2 carbon dioxide holding pipe 2520 is formed to protrude from the lower surface of the 2-1 carbon dioxide holding pipe 2510 and is inserted into the second flow pipe insertion portion 2120, and has an outer diameter of the second carbon dioxide flow pipe ( 2300), the inner diameter is formed the same as the outer diameter of the carbon dioxide compression pipe 2600, and the end of the 2-2 carbon dioxide holding pipe 2520 is the other end of the carbon dioxide compression pipe 2600. The end portion is formed to be longer than the end portion so that the carbon dioxide discharged from the carbon dioxide compression pipe 2600 passes through the interior of the 2-2 carbon dioxide holding pipe 2520.

One end of the second carbon dioxide flow pipe 2300 is inserted into the second flow pipe insertion portion 2120, and is interposed and coupled between the 2-2 carbon dioxide holding pipe 2520 and the second flow pipe insertion portion 2120. The other end of the second carbon dioxide flow pipe 2300 is disposed at the center of the gas injection hole 1622.

As a result, the carbon dioxide is transferred in a liquid state from the carbon dioxide supply unit 3000 to the carbon dioxide supply passage 1110, and the carbon dioxide moves from the carbon dioxide supply passage 1110 to the first flow pipe insertion portion 2110. Then, as it moves from the carbon dioxide compression pipe 2600 to the 2-2 carbon dioxide holding pipe 2520, it undergoes primary adiabatic expansion, and from the 2-2 carbon dioxide holding pipe 2520 to the second carbon dioxide flow pipe 2300. ), it undergoes secondary adiabatic expansion, and as it is discharged to the outside from the second carbon dioxide flow pipe 2300, it undergoes tertiary adiabatic expansion, making it possible to stably inject carbon dioxide in the state of dry ice.

In addition, the air is supplied from the air supply unit 4000 to the air supply space 1330 through the first air movement passage 1320 formed in the air supply block 1300, and then the first carbon dioxide is injected. After moving the second air movement passage 1420 formed in the nozzle holding block 1400 and the third air movement passage 1512 formed in the 2-1 carbon dioxide injection nozzle holding block 1510, the gas By being injected into the injection hole 1622, the carbon dioxide injected from the second carbon dioxide flow pipe 2300 is carried by the air and is injected, making it possible to control the injection speed of the carbon dioxide.

That is, the end of the second carbon dioxide flow pipe 2300 is disposed at the center of the gas injection hole 1622, and the outer surface of the second carbon dioxide flow pipe 2300 is consistent with the inner surface of the gas injection hole 1622. They are arranged to be spaced apart, and accordingly, the air of the second gas movement passage 1621 is injected from the area between the outer surface of the other end of the carbon dioxide injection nozzle 2000 and the inner surface of the gas injection hole 1622, The carbon dioxide is injected from the end of the second carbon dioxide flow pipe 2300.

As described above, preferred embodiments of the present invention have been shown and described with reference to the drawings, but the present invention is not limited to the specific embodiments described above, and the present invention is not limited to the above-described specific embodiments, and the present invention can be modified without departing from the gist of the present invention as claimed in the patent claims. Of course, various modifications can be made by those skilled in the art in the technical field to which the invention pertains, and these modified embodiments should not be understood individually from the technical idea or perspective of the present invention.

1000: Complex fluid injection assembly
1100: Carbon dioxide supply block
1110: Carbon dioxide supply channel
1111: First carbon dioxide supply channel
1112: Second carbon dioxide supply channel
1200: Carbon dioxide distribution block
1210: First carbon dioxide distribution block
1211: First carbon dioxide distribution channel
1220: Second carbon dioxide distribution block
1221: Carbon dioxide diffusion channel
1222: Second carbon dioxide distribution channel
1222a: 2-1 carbon dioxide distribution channel
1222b: 2-2 carbon dioxide distribution channel
1300: Air supply block
1310: First flow pipe insertion hole
1320: 1st air movement channel
1330: Air supply space
1400: First carbon dioxide injection nozzle holding block
1410: Second flow pipe insertion hole
1420: Second air movement channel
1500: Second carbon dioxide injection nozzle holding block
1510: 2-1 carbon dioxide injection nozzle holding block
1511: First holding pipe insertion hole
1512: Third air movement channel
1520: 2-2 carbon dioxide injection nozzle holding block
1521: Fixing part
1522: Joint
1522a: Second holding pipe insertion hole
1522b: Third flow pipe insertion hole
1600: Gas injection block
1610: Combination block
1611: First gas transfer channel
1620: Spray block
1621: Second gas transfer channel
1622: Gas injection hole
2000: Carbon dioxide injection nozzle
2100: Outer holding pipe
2110: First flow pipe insertion part
2120: Second flow pipe insertion part
2130: Compression tube insertion part
2200: First carbon dioxide flow pipe
2300: Second carbon dioxide flow pipe
2400: First carbon dioxide holding pipe
2410: First compression pipe insertion hole
2500: Second carbon dioxide holding pipe
2510: No. 2-1 carbon dioxide holding pipe
2520: 2-2 carbon dioxide holding pipe
2600: Carbon dioxide compression tube
3000: Carbon dioxide supply department
4000: Air supply unit

Claims (3)

In a carbon dioxide spray cleaning device that removes foreign substances by spraying carbon dioxide on the object to be cleaned,
a composite fluid injection assembly that receives carbon dioxide and air and sprays the air into a plurality of gas injection holes formed on a surface facing the cleaning object;
A carbon dioxide injection nozzle disposed inside the composite fluid injection assembly, wherein the carbon dioxide supplied to the composite fluid injection assembly flows into one end, and the carbon dioxide is injected into the other end, and the other end is disposed at the center of the gas injection hole. ;
a carbon dioxide supply unit supplying the carbon dioxide to the composite fluid injection assembly;
An air supply unit that supplies the air to the composite fluid injection assembly,
The complex fluid injection assembly,
A carbon dioxide supply block that receives the carbon dioxide supplied from the carbon dioxide supply unit to the inside;
a carbon dioxide distribution block disposed below the carbon dioxide supply block to distribute the carbon dioxide into a plurality of carbon dioxide distribution blocks;
An air supply block disposed below the carbon dioxide distribution block to receive the air inside;
a first carbon dioxide injection nozzle holding block and a second carbon dioxide injection nozzle holding block disposed below the air supply block, penetrating the carbon dioxide injection nozzle, and moving the air downward; and
It includes a gas injection block disposed below the second carbon dioxide injection nozzle holding block and having the gas injection hole for spraying the carbon dioxide and the air.
The carbon dioxide supply block is,
A first carbon dioxide supply passage coupled to the carbon dioxide supply unit to receive the carbon dioxide; and
It includes a second carbon dioxide supply channel arranged to be vertically connected to the first carbon dioxide supply channel,
The carbon dioxide distribution block is,
a first carbon dioxide distribution passage formed in an area corresponding to an area where the second carbon dioxide supply passage is formed;
a carbon dioxide diffusion passage connected to the first carbon dioxide distribution passage to allow the carbon dioxide to diffuse; and
It includes a second carbon dioxide distribution passage connected to the carbon dioxide diffusion passage and formed in a number corresponding to the number of carbon dioxide injection nozzles,
The air supply block further includes a first flow pipe insertion hole through which the carbon dioxide injection nozzle passes,
The first carbon dioxide injection nozzle holding block includes a second flow pipe insertion hole through which the carbon dioxide injection nozzle passes,
The second carbon dioxide injection nozzle holding block includes a first holding pipe insertion hole through which the carbon dioxide injection nozzle passes and a second holding pipe insertion hole formed to be spaced downward from the first holding pipe insertion hole,
The diameters of the first flow pipe insertion hole and the second flow pipe insertion hole are the same, and the diameters of the first holding pipe insertion hole and the second holding pipe insertion hole are larger than the diameters of the first flow pipe insertion hole and the second flow pipe insertion hole. ,
The outer surface of the other end of the carbon dioxide injection nozzle is disposed to be spaced apart from the inner surface of the gas injection hole, and the air is injected from the area between the outer surface of the other end of the carbon dioxide injection nozzle and the inner surface of the gas injection hole. Carbon dioxide injection cleaning device. delete According to paragraph 1,
A carbon dioxide injection cleaning device, characterized in that the inner diameter of the other end of the carbon dioxide injection nozzle expands toward the end so that the carbon dioxide sprayed from the carbon dioxide injection nozzle adiabatically expands.

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