KR100295501B1 - The mouth piece for flat jet nozzle - Google Patents

Abstract

The present invention relates to a two-component nozzle for injecting gas, liquid mixtures, in particular air, water mixtures. While simple to produce, the liquid is sprayed in the form of a spray solution from the wall of the mixing chamber in advance so that the two media mix well before reaching the nozzle inlet, mixing the entire interior of the mixing chamber to mix the liquid and gas. A two-component nozzle that eliminates installations inside the chamber and installs a liquid spray nozzle on the mixing chamber wall or a rebounding cavity opposite the liquid inlet inside the mixing chamber to reflect the ruptured spray liquid into the mixing chamber. present.

Description

Two-component nozzles {The mouth piece for flat jet nozzle}

The present invention relates to a two-component nozzle for injecting gas, liquid mixtures, in particular air, water mixtures.

The two-component nozzle includes a mixing chamber having a first inlet for introducing a gaseous medium supplied under pressure. Opposite to the first inlet is a spout with a nozzle mouthpiece. The two-component nozzle also includes a second inlet port, wherein the pressurized spray liquid is substantially perpendicular to the axis of the first inlet port and flows into the mixing chamber through the second inlet port.

Two-component nozzles of this type are already known (DE 39 15 210 C2). In the conventional two-component nozzle, a rod-shaped injection insert having a cylindrical blind hole is inserted into a cylindrical mixing chamber through which the pressurized gas medium is axially penetrated. Insert it vertically. A blind hole is provided from the blind hole toward the outside, and the spray hole is roughly connected to the center of the mixing chamber. Such an injection port allows the jetting liquid ejected through the injection port to be ejected across the direction in which the fluid flows, or even in a direction in which the fluid flows while being inclined at a steep angle. The jetting liquid which bursts when ejected by the above is preliminarily nebulized by the shear force caused by the jetting gas striking above the jetting liquid, and the mixture of gas and water formed thereby is ejected from the nozzle inlet. This type of spray nozzle requires a relatively high manufacturing cost due to the insert protruding into the mixing chamber. In addition, there are many cases that are not suitable for application.

In the case of this type of structure, the sprayed liquid is impinged on a flat baffle plate, and the gas stream rubs the baffle plate, thereby mixing the sprayed burst liquid with the gas stream and blowing nozzles. It is also known to lead towards (DE 31 31 070 C2). In the above, the baffle plate is disposed on a table protruding to the side of the inside of the mixing chamber in the center of the mixing chamber. The above-described spray nozzles are also expensive because of the table arranged to be perpendicular to the axis of the injection gas. Sometimes water does not mix uniformly. This is because it is not uniformly mixed throughout the mixing chamber because of the asymmetry. Other structures have been introduced for the same reason as described above (DE-A 2 252 218). In this case, the jetting liquid impinging on the baffle plate and atomized is captured by a swirl flow caused by lateral inflow, and is led outward into the outlet through the edge of the baffle plate. In the outlet, the secondary impact is applied to the mixed spray. Such a spray nozzle takes a lot of manufacturing cost compared to the above-described structure. The same is true for other conventional spray nozzles for producing a two-component mixture (US-A 5 240 183). In this case, the gas and the liquid are supplied on the same axis as the jet nozzle, and a vortex insert is disposed in the center of the mixing chamber provided in front of the jet nozzle. However, in the above case, it is difficult to supply the bicomponent mixture on the same axis.

The present invention was devised to solve various problems of the conventional two-component nozzle as described above, and the object of the present invention is to simplify the production, while mixing the liquid so that the two media are mixed well before reaching the nozzle inlet. By spraying in advance in the form of a spray solution from the walls of the chamber, the entire interior of the mixing chamber is used to mix liquids and gases, eliminating the need for installations inside the mixing chamber, and installing liquid spray nozzles on the mixing chamber walls or rebounding cavities. It is to provide a two-component nozzle that is installed opposite the liquid inlet inside the mixing chamber to reflect the ruptured spray liquid into the mixing chamber.

1 shows an example of a two-component nozzle with an X-shaped vortex insert

2 shows an example of a two-component nozzle with milled vortex inserts.

3 shows an example of a two-component nozzle with a punctured vortex insert

Figure 4 is an illustration showing a two-component nozzle containing a nebulized insert of the spraying characteristics

5 illustrates an example of various embodiments of a rebound cavity.

6 is a longitudinal cross-sectional view of a two-component spray nozzle in which a liquid spray nozzle with an X-shaped vortex insert made according to the present invention is disposed;

FIG. 7 is a plan view of the liquid jet nozzle viewed from the direction of arrow III in FIG. 6.

8 is an exemplary view showing a mixing process in the spray nozzle according to FIG. 6

FIG. 9 is a view similar to FIG. 6, illustrating an example of a reduced liquid jet nozzle in which a milled vortex insert is installed.

FIG. 10 is a plan view of the liquid jet nozzle viewed from the direction of arrow V in FIG. 9.

FIG. 11 is a view similar to FIG. 9, illustrating an example of a reduced liquid ejection nozzle provided with a punched vortex insert.

12 is a plan view of the liquid jet nozzle seen from the arrow direction of FIG.

FIG. 13 is a view similar to FIG. 9, illustrating a liquid jet nozzle in which a nebulization insert having a flat spray characteristic is installed; FIG.

FIG. 14 is a plan view of the liquid jet nozzle seen in the arrow direction of FIG. 13. FIG.

15 is a longitudinal cross-sectional view of a two-component nozzle of another embodiment.

16 is an exemplary view showing a spraying and mixing process in a two-component nozzle according to FIG.

17 is a longitudinal cross-sectional view of the two-component nozzle in which another form of rebounding cavity is installed in FIG. 15.

18 is an exemplary view showing a spraying and mixing process in a two-component nozzle according to FIG.

<Description of the symbols for the main parts of the drawings>

1 case 2 mixing chamber

2a: wall 3,25: axis

4: first inlet port 5: pipe union (first screw socket)

6,13: Female thread 7,14,18,19,27: Arrow

8: pipe part 9, 90: injection nozzle

10: discharge groove 11: the second inlet

12: 2nd screw socket 15a: atomized water

16 chamber 17 X-shaped vortex insert

17a, 21a, 22a, 23: hole 20: vortex insert with milling

20a: cutting part 21: perforated vortex insert

22: Original 24: Prism

26, 28: rebound joint 29: spout

35: two-phase mixture 39: reflected water

51 gas inlet 52 liquid inlet

54: joint pipe 55: mouthpiece

80: pipe socket 100: case

120: projection

In order to achieve the above object, the present invention starts from the idea that it is effective to use the entire cross section of the mixing chamber when mixing two media. A feature of the invention is that at least one mixing chamber wall portion overlying the axis of the second inlet in a two-component nozzle of the type described above is deformed in the form of an injection which almost completely fills the mixing chamber, and thus the starting point of the injection liquid at least once. Thus, the present invention does not install any inserts that protrude on one side of the interior of the mixing chamber and affect the flow conditions. Instead, it creates a spray that starts at the wall of the mixing chamber and is mainly perpendicular to the gas flow, and captures the spray as a gas stream that flows across the cross section of the mixing chamber throughout the cross section of the mixing chamber, thereby allowing the spray to And mix best.

The present invention can be realized very simply through the embodiment in which the second inlet is formed by the inlet of the spray liquid nozzle disposed in the wall portion of the mixing chamber.

In the above case, a spray liquid nozzle having a conventional structure can be used. The conventional spray nozzle may be provided with a pre-atomizing device having, for example, an X-shaped vortex insert, a milled vortex insert, a punched vortex insert, or a nebulization insert having a flat spray characteristic.

The pre-spray and the atomization insert of the device and the spraying characteristics described above with reference to the accompanying Figures 1 to 4 as follows.

In general, the two-component nozzle is generally used for the gas inlet 51 and the liquid inlet 52, the mixing chamber (2), the joint pipe (54) connecting the mixing chamber and the mouthpiece, mainly spraying the liquid, air mixture ( A device comprising a nozzle mouthpiece 55 for atomizing in the form of a flat jet.

In the above two-component nozzle, the liquid inlet 52 has a preliminary atomizer that operates according to the principle of the classical one-component nozzle. The preliminary atomizer includes an X-swirl insert 17, a milled vortex insert 20, a punched vortex insert 21, a flat spray nozzle 9, and the like. . In all of these cases the liquid is presprayed into the mixing chamber so that the liquid is already evenly dispersed in the form of droplets. After this, the air / water mixture that reaches the mouthpiece via the joint pipe is somewhat uniformly dispersed throughout the pipe cross section, and is evenly atomized through the nozzle mouthpiece 55.

1-4 show various examples of such a preliminary atomizing device in side and plan view.

1 is an exemplary view showing a two-component nozzle with an X-shaped vortex insert.

Figure 2 is an exemplary view showing a two-component nozzle containing a milled vortex insert.

3 is an exemplary view showing a two-component nozzle including a punched vortex insert.

4 is an exemplary view showing a two-component nozzle including a nebulized insert having a flat spray property.

The conventional preliminary atomizer as described above operates in principle as follows.

The X-shaped vortex insert 17 shown in FIG. 1 has a hole in which water rotates at the crossed X. As a result, the water is atomized into a hollow cone.

The milled vortex insert 20 shown in FIG. 2 has a milling cut portion 20a that abuts the circumference at an angle to the disc. As a result, the water is atomized into a hollow cone.

The punched vortex insert 21 shown in FIG. 3, unlike the milled vortex insert, in this case inserts the hole 21a into the disc at an angle while contacting the circle. As a result, water is sprayed into a hollow cone.

The flat jet characteristic atomized insert 22 shown in FIG. 4 has a circular hole cut by a prism in a conventional manner. The resulting lenticular hole 22a atomizes the water in the form of a flat spray.

Further, when the invention according to the above embodiment is further developed, it is also effective to arrange the baffle plate disposed on the wall of the mixing chamber so as to face the second inlet. The jetting liquid impinges on the baffle plate for the purpose of atomization and is reflected back into the mixing chamber.

In addition, the present invention can produce the baffle plate as part of a cavity disposed in the wall of the mixing chamber facing the second inlet. When fabricated as described above, the atomized and reflected jetting liquid component almost completely fills the mixing chamber. The cavity can be fabricated in the form of a rotationally symmetrical rebound cavity. The rebound cavity may be manufactured in the form of a spherical zone, in the form of a part of a paraboloid, or in the form of a cone. Through all these structures, a spray liquid is produced inside the mixing chamber, and the components contained in the spray liquid are captured by the gas flow flowing through the components, and the components of the spray liquid are uniformly dispersed and mixed with the gas stream. The rebounding cavity will be described in detail with reference to the accompanying drawings.

5 is an exemplary diagram illustrating various embodiments of a rebounding cavity.

Referring to FIG. 5, a typical two-component nozzle includes a mixing chamber 2, in which a gaseous phase 7 and a liquid phase 14 are introduced into the mixing chamber 2 through an appropriate inlet. Inflow. On the wall of the mixing chamber 2 there is a rebounding hollow 26 which impinges upon the rebounding cavity 26 a liquid phase 14 to atomize and reflects into the mixing chamber according to the shape of the cavity 26. Let's do it. The atomized water 15a is captured in the gaseous phase 7 and blown out of the mixing chamber 2 in the form of a two-phase mixture 35 to finely atomize air and water in the mouthpiece 55. Spread out in the form of mixture 15b. The rebounding cavity may have various embodiments. The cavity may be conical or hemispherical. The surface inclined from the cavity is manufactured so that the reflected water 39 completely fills the inside of the mixing chamber 2. The two-phase mixture 35 leaving the mixing chamber by the nozzle of this type with a preliminary atomization device is dispersed as evenly as possible over the discharge cross section. As a result, the spray angle is high, the liquid is uniformly dispersed, and uniform atomization is performed in the mouthpiece 6 while the droplet spectrum is uniformly maintained.

Hereinafter, with reference to the accompanying drawings with respect to the configuration and operation of the embodiment of the present invention will be described.

6 is a longitudinal cross-sectional view of a two-component spray nozzle in which a liquid spray nozzle with an X-shaped vortex insert made in accordance with the present invention is disposed.

FIG. 7 is a plan view of the liquid jet nozzle seen from the direction of arrow III in FIG. 6.

8 is an exemplary view illustrating a mixing process in the spray nozzle according to FIG. 6.

FIG. 9 is an exemplary view similar to FIG. 6 in which a liquid jet nozzle with a milled vortex insert is installed.

FIG. 10 is a plan view of the liquid jet nozzle viewed from the direction of arrow V in FIG. 9.

FIG. 11 is an exemplary view similar to FIG. 9, illustrating a liquid jet nozzle in which a punched vortex insert is installed.

FIG. 12 is a plan view of the liquid jet nozzle seen from the arrow direction in FIG. 11. FIG.

FIG. 13 is an exemplary view similar to FIG. 9, illustrating a liquid jet nozzle in which a nebulization insert having a flat spraying property is installed.

FIG. 14 is a plan view of the liquid jet nozzle seen from the arrow direction in FIG. 13. FIG.

15 is a longitudinal cross-sectional view of a two-component nozzle of another embodiment.

FIG. 16 is an exemplary view illustrating a spraying and mixing process in the two-component nozzle according to FIG. 15.

FIG. 17 is a longitudinal cross-sectional view of the two-component nozzle in which another form of rebounding cavity is provided in FIG. 15.

18 is an exemplary view illustrating a spraying and mixing process in the two-component nozzle according to FIG. 17.

6 and 7 are exemplary views showing a two-component nozzle according to the present invention, in which a cylindrical mixing chamber 2 is disposed inside the nozzle case 1 of the two-component nozzle. The axis of the first inlet 4 which forms part of the pipe union (first threaded socket) 5 screwed to the front of the case 1 coincides with the axis 3 of the mixing chamber 2. The inner hole of the pipe union 5 is reduced in a stepped manner to the inlet 4, and the pipe union 5 is provided with a female screw 6 for fixing, for example, a pressure hose or a pressure pipe. The medium is introduced into the mixing chamber 2 in the direction of the arrow 7 while applying pressure to a medium in a gaseous state such as air through the pipe union 5, and mixed with a liquid in a manner described below. The air and liquid mixture produced inside the mixing chamber 2 is continuously blown out of the mixing chamber 2 through the outlet port 29 opposite the inlet 4 along the shaft 3, and the tube portion Guided by the two-component injection nozzle (9) through (8). The two-component injection nozzle 9 has a discharge groove 10. The discharge groove 10 may be used for the purpose of cooling after discharging the air, liquid mixture, that is, the air and water mixture from the discharge groove 10 in this case.

The case 1 has a second inlet 11 which is part of the second screw socket 12. The second inlet 11 is arranged in front of the case 1 facing towards the mixing chamber 2, and as a result forms part of the wall of the mixing chamber 2. Similarly to the first screw socket 5, the second screw socket 12 has a female screw 13, and the inside of the female screw 13 can supply water into the mixing chamber 2 in the direction of the arrow 14. Pressure hoses or pressure tubes can be fixed. The inlet and the shaft 25 of the chamber located in front of the inlet intersect perpendicularly to the axis 3 of the mixing chamber 2. A part 15 located in front of the second inlet 11 leading to the mixing chamber 2 from the inside of the second screw socket 12 and in front of the chamber 16 gradually narrowing toward the second inlet 11. Insert an X-shaped vortex insert 17 into The X-shaped vortex insert 17 is the part with the hole 17a in the form of the crossed X-shape (see Fig. 7). The water is rotated through the hole 17a. When the water introduced while the pressure in the direction of the arrow 14 through the above process is introduced into the mixing chamber (2) is to be atomized into a full cone.

8 shows the operation of the two-component nozzle as described above. In the above, it can be seen that water is introduced into the mixing chamber 2 in the direction of the arrow 14 in the form of a spray liquid sprayed according to the arrow 18. An appropriate nozzle or insert 17 is selected above so that the injection liquid can almost completely fill the interior of the mixing chamber 2. The atomized spray water flows in the direction of the arrow 7 with air after the above process while the fine droplets form a solid cone. As a result, the air and water components mixed very uniformly in the mixing chamber 2 are led to the outside of the mixing chamber 2 in the direction of the arrow 19. In the same manner as in FIG. 8, almost all of the inside of the mixing chamber may be used for mixing the liquid and the gaseous medium, and it is clear that fine and uniform mixing is possible.

In Figs. 9 to 13, each showing a spray nozzle having a structure similar to that of Fig. 6, the same reference numerals are given to the same parts as those in Fig. 6. Hereinafter, a difference from the embodiment of FIG. 6 will be described.

9 and 10 are similar to the two-component injection nozzle of FIG. 6, but with the milled vortex insert 20 inserted into the second screw socket 12. In the case of the vortex insert 20, the milling cutting part 20a is placed on the disc at a constant angle with respect to the circumference. The atomized spray water is thus ejected in contact with the wall of the mixing chamber 2 in a hollow cone from the second inlet 11 leading to the mixing chamber 2. Also in this case, the atomized sprayed water is captured by the air supplied under pressure in the direction of the arrow 7, mixed with air, and then the mixture is directed toward the spray nozzle 9 in the direction of the arrow 19.

11 and 12 show a modified embodiment in that a perforated vortex insert, in the form of a disc 20, is inserted into the second screw socket 12. The hole 21a is obliquely inserted into the disc 21 so as to contact the circle. Even in this case, atomization takes place in a hollow cone. The injection liquid flows into the mixing chamber 2 through the second inlet 11 and is captured by the airflow flowing in the direction of the arrow 7.

13 and 14 show the modified embodiment in that the inlet port leading into the mixing chamber 2 is formed through the lenticular hole 22a. A lens-shaped hole 22a is inserted into the disc 22 inserted into the insert 12 by cutting the hemispherical end of the hole 23 with the prism 24 according to the conventional method.

In all the embodiments shown in FIGS. 6-14 above, the sprayed water in which the central axis 25 is substantially perpendicular to the axis 3 of the mixing chamber 2 is sprayed directly from the wall of the mixing chamber 2. While mixing with the next supplied air, the case of FIGS. 15-18 shows an embodiment different from the above. That is, although the sprayed water is sprayed starting from the wall of the mixing chamber 2 also in FIGS. 15-18, the sprayed water does not spray starting from one of the conventionally known liquid spray nozzles.

In the case of the embodiment illustrated in FIG. 15, the case 100 has a protrusion 120. The protrusions 120 directly include a stepped inlet as in the embodiment of FIGS. 5 to 14, and are introduced in the direction of the arrow 14 while applying pressure to the water through the inlet. For this purpose, the female screw 13 is installed in the protrusion 120 to insert a pressure hose or a pressure tube as in the above embodiment. In the above, the inlet shaft 25 is perpendicular to the shaft 3 of the mixing chamber 2 produced in a cylindrical shape. As in the other embodiment, the first inlet 4 extends in the axial direction into the mixing chamber 2 so that the shafts of the inlets disposed inside the first inlet 4 and the first screw socket 5 are mixed in the mixing chamber. It coincides with the axis 3 of (2). The compressed air is supplied in the direction of the arrow 7 through the first screw socket 5. Other structures are the same as in the above embodiments. However, in the above case, the installed pipe socket 80 is slightly shorter than other embodiments, and the injection nozzle 90 located at the end of the pipe has a slightly different shape. However, the injection nozzle 90 also has a discharge groove (10).

A cavity in the form of a conical rebound cavity 26 is placed on the wall 2a of the mixing chamber 2, which is located at the end of the conical chamber 16 opposite the second inlet 11. In the above, the conical shaft coincides with the shaft 25 of the inlet port in the protrusion 120. As can be seen in FIG. 16, the condensed rebound cavity 26 in the opposite wall 2a of the compact compressed spray water flowing into the mixing chamber 2 in the direction of the arrow 14 through the same process as described above. Hit by the center, decomposed into individual components by the energy inherent in the impact and compressed jet water, and then from the wall 2a in the direction of the arrow 27 by the inclined surface of the rebounding cavity 26 the mixing chamber 2 Reflected inward. The rebounding cavity 26 is manufactured in an appropriate form so that the spray liquid completely fills the inside of the mixing chamber 2, and the above phenomenon occurs. Even in this case, the reflected spray liquid is captured by the air stream flowing in the direction of the arrow 7, whereby the components of the spray liquid are mixed with the air stream in a state where they are dispersed throughout the cross section of the mixing chamber 2, and then the homogeneous formed by the above. Is supplied towards the nozzle 90 in the direction of arrow 19.

FIG. 17 shows an embodiment in which the cavity 28 overlying the axis 25 has the shape of a spherical surface that is rotationally symmetric about the axis 25. It may be possible to manufacture the cavity 28 in the form of a parabolic surface or a portion of a hyperbola instead of a spherical surface. In all such cases, however, the cavity 28 should be rotationally symmetrical about the axis 25, as with the rebounding cavity 26 of FIG. 15. In doing so, the spray liquid is sprayed in the direction of the arrow 27, reflected from the wall 2a of the mixing chamber 2 into the mixing chamber 2, and then the components of the spray liquid are flowed through the cross section of the mixing chamber. You can mix it while hitting it.

Through all the above processes, the two-component nozzle is implemented as the present invention intends.

As can be seen from the above description, the present invention is a two-component nozzle, in which a liquid is sprayed in the form of a spray liquid from the wall of the mixing chamber in advance, and the entire mixing chamber is used to mix the liquid and gas, Provides a two-component nozzle that eliminates the need for internal installations and installs a liquid jet nozzle on the mixing chamber wall or a rebounding cavity opposite the liquid inlet inside the mixing chamber to reflect the ruptured jet liquid into the mixing chamber. It can be produced simply and has the effect of mixing the two media well before reaching the nozzle inlet.

Claims (7)

The mixing chamber 2 comprises a first inlet 4 and a second inlet 11, the nozzle mouthpiece 9 opposite the first inlet 4 for introducing a gaseous medium supplied under pressure. ) Is provided with a jet port 29, and the injection liquid under pressure is introduced into the mixing chamber 2 through the second inlet port 11 while being perpendicular to the axis 3 of the first inlet port 4. In the two-component nozzle including the mixing chamber 2, The second inlet 11 is disposed to face the cavities 26 and 28 installed in the wall 2a of the mixing chamber 2, but the spray liquid hits the cavities 26 and 28 for the purpose of atomization. Two-component nozzles characterized in that. 4. A two-component nozzle according to claim 3, characterized in that the sprayed components of the walls of the cavities (26, 28) are reflected to fill the inside of the mixing chamber (2). The two-component nozzle according to claim 4, wherein the cavity (26.28) is rotationally symmetrical and the axis of the cavity (26.28) coincides with the axis (25) of the second inlet (11). The method according to claim 4 or 5, characterized in that the mixing chamber (2) is made in a cylindrical shape, and the axis (3) of the mixing chamber (2) is perpendicular to the axis (25) of the second inlet port (11). Two-component nozzle to be made. The two-component nozzle according to claim 6, wherein the shaft (3) of the mixing chamber (2) intersects the shaft (25) of the second inlet (11). 6. The two-component nozzle according to claim 5, wherein the rebounding cavity (26) is manufactured in the form of a spherical surface or in the form of a parabolic surface or a part of a hyperboloid surface. 6. A two-component nozzle according to claim 5, wherein the rebounding cavity is made conical.