KR20230144321A - Mist spray nozzle - Google Patents

Abstract

The present invention relates to a mist spray nozzle that sprays fluid by rotating it, comprising a body portion through which fluid flows in and is sprayed, a core portion coupled to one side of the body portion and through which fluid is rotated and sprayed by spiral rotation, and a body portion. It is characterized by including a socket portion coupled to the other side of the interior and connected to a supply facility through which fluid flows. Therefore, by providing a body part, a core part, and a socket part, the present invention rotates the fluid and sprays it in a mist state to improve the spraying performance of the mist, and at the same time prevents the phenomenon of splashing, cracking, and tilting when spraying the mist. Provides effective effects.

Description

Mist spray nozzle {MIST SPRAY NOZZLE}

The present invention relates to a mist spray nozzle, and more specifically, to a mist spray nozzle that rotates fluid and sprays it in a fog state.

Nozzles that spray a mixture of liquid and gas can be divided into internal mixing spray nozzles that mix inside the nozzle and external mixing spray nozzles that mix outside the nozzle, depending on the mixing location of the liquid and gas.

Among these, internal mixing type spray nozzles do not have independent flows of liquid and gas, and changes in gas flow affect the liquid flow. These internal mixing spray nozzles are used to cool and clean high-temperature gases containing a lot of dust, such as in plants that require multiple spray nozzles, such as converter facilities in steel mills. For this, liquid must be finely sprayed. It should be designed so that a greater number of spray nozzles can be operated from a given compressed air or compressed steam source.

Specifically, the liquid is supplied as a liquid jet through an orifice in the body and is crushed by colliding with the collision pin. The gas is released through the air supply section to form an air curtain around the liquid jet, and the air curtain is contracted by the air guide section and collides with the liquid jet to fog the liquid particles. The atomized particles expand inside the expansion chamber to prevent large particles from being reformed, and are further atomized by being sprayed from the expansion chamber into the atmosphere through a plurality of spaced orifices formed in the expansion chamber.

However, according to the above conventional spray nozzle, when the pressure of the supplied compressed air is low, atomization does not proceed sufficiently, and some of the atomized liquid particles emitted to the outside combine with other particles, ultimately causing the particles to increase in size. There was a problem with this.

In addition, the spraying distance of the particles sprayed from each spaced orifice is short, and as the speed of the liquid particles sprayed to the outer part of the spray area becomes lower compared to the central part of the spray area, there is a problem in that the particles recombine and the size of the particles increases. .

In particular, mist spray nozzles are increasingly used in processes such as deposition, lithography, etching, chemical/mechanical polishing, cleaning, and drying when producing semiconductor substrates. However, in the conventional mist injection nozzle as described above, in order to spray the injection liquid, the injection liquid and gas must be supplied at the same time, so if the hydraulic pressure for supplying either fluid becomes greater, the fluid may flow back or the fluid may not be sprayed smoothly. There is a problem that cannot be supported.

In addition, in conventional mist spray nozzles, the housing through which fluid flows is formed in a tubular shape, and in order to couple a plurality of nozzle heads to this tubular housing, the housing is cut to form a head coupling surface, so the strength of the housing is reduced. Also, there was a problem that the length of the housing could not be made long.

In addition, the distribution of spray from the spray at a short distance from the nozzle is not uniform, and there are places where spray does not exist, so this nozzle row cannot be used at a close location where the spray speed to the object to be cleaned is highest, and the distribution Although it is continuous, it has no choice but to be used in separated positions where the spray speed is reduced. For this reason, there was also a problem that the actually obtained spray impact and cleaning effect were attenuated.

In addition, in existing mist spray nozzles, the size and distribution of spray particles sprayed through the nozzle of the nozzle body are not constant, resulting in product defects and increased fluid consumption, which is another problem.

Republic of Korea Patent No. 10-1091088 (December 9, 2011) Republic of Korea Patent Publication No. 10-2018-0106945 (October 1, 2018) Republic of Korea Patent No. 10-0162154 (January 15, 1999)

The present invention was devised to solve the problems of the prior art as described above. By providing a body part, a core part, and a socket part, the fluid is rotated and sprayed in a fog state to improve the spraying performance of the mist, and at the same time, the spraying performance of the mist is reduced when the mist is sprayed. The purpose is to provide a mist spray nozzle that can prevent cracking, cracking, and tilting phenomena.

In addition, the present invention is first-class by providing a body portion with a first injection body, a first connection piece, a first fitting hole, a first communication hole, a first inclined hole, a first inlet hole, a first injection hole, and a first guide piece. Improve the mist particle injection performance of the sieve, optimize the size of the orifice to match the fluid particles and flow rate, maintain the quality of the nozzle with sharp edges, and create a mist injection nozzle that can maintain the uniformity of the hollow cone pattern. Another purpose is to provide

In addition, the present invention has four orifices by providing a second jet, a second inclined piece, a second coupling piece, a second connection hole, a second extension hole, a second communication hole, and a second spiral groove as the core portion. Another purpose is to provide a mist spray nozzle that can improve the rotational force of the fluid and optimize the size and ratio of the spiral groove to improve the rotational force.

In addition, the present invention facilitates the connection between the body and the fluid supply equipment and improves the fluid supply performance inside the body by providing a socket, a fitting piece, an inlet hole, a separation piece, and a separation groove as the socket portion. Another purpose is to provide a mist spray nozzle that can

In addition, the present invention provides a mist system that further provides a mesh portion outside the socket portion, thereby filtering foreign substances contained in the fluid supplied from the fluid supply facility to improve the mistization of the fluid and prevent contamination or clogging of the fluid passage. Another purpose is to provide a spray nozzle.

The present invention for achieving the above object is a mist spray nozzle that rotates and sprays fluid, including a body portion 10 into which fluid flows and is sprayed; A core portion (20) coupled to one inner side of the body portion (10), through which fluid is rotated and sprayed by spiral rotation; And a socket portion 30 coupled to the other inner side of the body portion 10 and connected to a supply facility through which fluid flows.

The body portion 10 of the present invention includes a first jet to which the core portion 20 and the socket portion 30 are connected to allow fluid to flow; A first connection piece installed around the other side of the first jet and connected to a supply facility through which fluid flows; a first fitting hole formed inside the other side of the first jet, into which the socket portion 30 is fitted; a first communication hole formed inside one side of the first injection body and coupled to communicate with the core portion 20; a first inclined hole formed to be inclined at one end of the inner part of the first jet to obliquely move the fluid flowing in from the core portion 20; a first inlet hole that is formed to be reduced at an inner end of the first jet and rotates the fluid flowing in from the core portion 20; a first injection hole formed through an enlarged end of the first injection body to spray the fluid rotated in the core portion 20 in a fog state; and a first guide piece that protrudes around the outer periphery of the first injection hole and guides the sprayed fluid in a fog state.

The core portion 20 of the present invention is fitted to one side of the body portion 10, and includes a second jet through which fluid flows through spiral rotation. a second inclined piece formed to be inclined on one side of the second jet and inserted into the body portion 10; a second coupling piece that protrudes from the other side of the second jet and is fitted into the body portion 10; a second connection hole formed on the other side of the second injection body and connected to the socket portion 30; a second extension hole formed on the other side of the second injection body and extending to be narrowed to the second connection hole; a plurality of second communication holes formed around the outer periphery of the second extension hole and communicating with the body portion 10; and a plurality of second spiral grooves formed in a spiral shape around the outer periphery of the second inclined piece.

The socket portion 30 of the present invention includes a socket fitted into the other side of the body portion 10; A fitting piece protruding from one end of the socket and fitted into the body portion 10; an inlet hole formed inside the socket through which fluid flows; A plurality of spaced pieces protrude and are spaced apart from each other around the outer periphery of the socket to form an inflow passage for fluid from the outside to the inside of the socket; and a separation groove formed between the separation pieces through which fluid flows.

In addition, the present invention is characterized in that it further includes a mesh portion 40 installed around the outer periphery of the socket portion 30 to filter the incoming fluid.

As discussed above, the present invention improves the spraying performance of the mist by rotating the fluid and spraying it in a fog state by providing a body portion, a core portion, and a socket portion, and at the same time prevents the phenomenon of splashing, cracking, and tilting when spraying the mist. Provides an effect that can prevent.

In addition, the body part is provided with a first injection body, a first connection piece, a first fitting hole, a first communication hole, a first inclined hole, a first inlet hole, a first injection hole, and a first guide piece, so that the mist of the hydraulic body is provided. It improves particle injection performance, optimizes the size of the orifice to match the fluid particles and flow rate, maintains the quality of the nozzle due to sharp edges, and maintains the uniformity of the hollow cone pattern.

In addition, the core portion is provided with a second injection body, a second inclined piece, a second coupling piece, a second connection hole, a second extension hole, a second communication hole, and a second spiral groove, so that the fluid is discharged using four orifices. It provides the effect of improving the rotational force and optimizing the size and ratio of the spiral groove to improve the rotational force.

In addition, by providing a socket, a fitting piece, an inlet hole, a separation piece, and a separation groove as the socket portion, the connection between the body portion and the fluid supply facility can be facilitated and the fluid supply performance inside the body portion can be improved. Provides effect.

In addition, by further providing a mesh portion on the outside of the socket portion, foreign substances contained in the fluid supplied from the fluid supply facility are filtered out, thereby improving the mistization of the fluid and providing the effect of preventing contamination or clogging of the fluid passage. .

1 is a perspective view showing a mist spray nozzle according to an embodiment of the present invention.
Figure 2 is a plan view showing a mist spray nozzle according to an embodiment of the present invention.
Figure 3 is a front view showing a mist spray nozzle according to an embodiment of the present invention.
Figure 4 is a rear view showing a mist spray nozzle according to an embodiment of the present invention.
Figure 5 is an exploded perspective view showing a mist spray nozzle according to an embodiment of the present invention.
Figure 6 is a cross-sectional perspective view showing a mist spray nozzle according to an embodiment of the present invention.
Figure 7 is an enlarged view showing a portion of the body portion of a mist spray nozzle according to an embodiment of the present invention.
Figure 8 is an exploded cross-sectional view showing a mist spraying nozzle according to an embodiment of the present invention.
Figure 9 is a state diagram showing the coupled state of the cap portion to the mist spray nozzle according to an embodiment of the present invention.
Figure 10 is a cross-sectional view showing the coupled state of the cap portion to the mist spray nozzle according to an embodiment of the present invention.
Figure 11 is a front view showing the core portion of a mist spray nozzle according to an embodiment of the present invention.
Figure 12 is a plan view showing the core portion of a mist spray nozzle according to an embodiment of the present invention.

Hereinafter, a preferred embodiment of the present invention will be described in more detail with reference to the accompanying drawings.

Figure 1 is a perspective view showing a mist spraying nozzle according to an embodiment of the present invention, Figure 2 is a plan view showing a mist spraying nozzle according to an embodiment of the present invention, and Figure 3 is a mist spraying nozzle according to an embodiment of the present invention. It is a front view showing a spray nozzle, Figure 4 is a rear view showing a mist spray nozzle according to an embodiment of the present invention, Figure 5 is an exploded perspective view showing a mist spray nozzle according to an embodiment of the present invention, and Figure 6 is a It is a cross-sectional perspective view showing a mist spraying nozzle according to an embodiment of the present invention, Figure 7 is an enlarged view showing a part of the body portion of the mist spraying nozzle according to an embodiment of the present invention, and Figure 8 is an embodiment of the present invention. It is an exploded cross-sectional view showing the mist spray nozzle by , Figure 9 is a state diagram showing the coupled state of the cap portion to the mist spray nozzle according to an embodiment of the present invention, and Figure 10 is a mist spray nozzle according to an embodiment of the present invention. It is a cross-sectional view showing the assembled state of the cap part, Figure 11 is a front view showing the core part of the mist spray nozzle according to an embodiment of the present invention, and Figure 12 is a plan view showing the core part of the mist spray nozzle according to an embodiment of the present invention. .

As shown in FIGS. 1 to 6, 9, and 10, the mist spray nozzle according to an embodiment of the present invention includes a body portion 10, a core portion 20, a socket portion 30, and a mesh portion ( 40) and a cap portion 50, and is a mist spray nozzle that rotates and sprays fluid.

The body portion 10 is a spraying member through which fluid flows in and is sprayed. As shown in FIGS. 5 and 8, the body portion 10 includes a first spraying body 11, a first connecting piece 12, a first fitting hole 13, and a first spraying member 10. It consists of a communication hole (14), a first inclined hole (15), a first inlet hole (16), a first injection hole (17), and a first guide piece (18).

The first jetting body 11 is a jetting member in which the core portion 20 and the socket portion 30 are connected to allow fluid to flow in, and is made of a nozzle member formed in a cylindrical shape, with the core portion 20 and the socket portion ( A first fitting hole 13 is formed to be coupled to 30).

The first connecting piece 12 is a connecting member installed around the other side of the first jet 11 and connected to a supply facility through which fluid flows, and a spiral groove is formed around the outer circumference of the first connecting piece 12. Of course, it is possible to be fastened and connected to a fluid supply facility.

The first fitting hole 13 is a fitting member formed inside the other side of the first jetting body 11 and into which the core portion 20 and the socket portion 30 are fitted. It consists of a fitting hole formed from one side to the other inside, and the core portion 20 and the socket portion 30 are fitted and coupled thereto.

The first communication hole 14 is a communication member formed inside one side of the first injection body 11 and coupled to communicate with the core portion 20, and is formed on one side of the inside of the first injection body 11. 1 It is formed to extend from the fitting hole 13 to form a separation space between it and the core part 20 to form a space for dividing and mixing fluid.

The first inclined hole 15 is an inclined member that is formed at an angle at an inner end of the first ejector 11 to obliquely move the fluid flowing in from the core portion 20, and is an inclined member at an inner end of the first ejector 11. It is formed inclined to reduce the cross-sectional area and is extended to the first communication hole 14 to accelerate and move the fluid by the inclined surface.

The first inlet hole 16 is a hole member that is formed to be reduced at the inner end of the first jet 11 and rotates the fluid flowing in from the core portion 20 while injecting it, and is a hole member of the first inclined hole 15. At one end, the cross-section is reduced and extended so that the fluid flowing in from the core portion 20 is rotated and introduced.

As shown in FIG. 7, the internal size (h2) of the first inlet hole 16 is formed to be reduced at a rate of 0.4 to 0.6 times the external size (h2), thereby increasing the speed of the incoming fluid and at the same time reducing the fog state. Of course, it is also possible to improve the hydraulic pressure to spray.

The first injection hole 17 is a hole member that is formed to extend through one end of the first injection body 11 and sprays the fluid rotated in the core portion 20 in a fog state, and the first inlet hole 16 ) is formed to extend at one end so that the cross section is expanded, and the fluid flowing in from the core portion 20 is rotated and sprayed in a fog state.

In addition, as shown in FIG. 7, the external size d2 of the first injection hole 17 is formed to be enlarged at a rate of 2.0 to 3.0 times the internal size d1, thereby increasing the speed of the incoming fluid. Of course, it is also possible to improve the spraying performance to spray in a fog state.

The first guide piece 18 is a guide member that protrudes around the outer periphery of the first injection hole 17 and guides the foggy fluid sprayed from the first injection hole 17. ) is rotated to guide the spray angle and spray range of the sprayed fluid to a predetermined space.

The core portion 20 is an injection member that is coupled to one side of the body portion 10 and rotates the fluid by spiral rotation to inject it. As shown in FIGS. 5 and 8, the second injection member 21 and the It consists of two inclined pieces (22), a second coupling piece (23), a second connection hole (24), a second extension hole (25), a second communication hole (26), and a second spiral groove (27).

The second jetting body 21 is a jetting member that is fitted to one side of the body part 10 and allows fluid to flow in through spiral rotation. At one end, a second inclined piece is coupled to the first inclined hole 15 ( 22) is formed to protrude, and a second coupling piece 23 is formed to protrude at the other end to be fitted into the first fitting hole 13.

The second inclined piece 22 is an inclined member that is formed to be inclined on one side of the second jetting body 21 and is inserted into the interior of the body portion 10. It is formed to protrude on one side of the second jetting body 21 and is inserted into the body portion 10. 1 It is inserted into the fitting hole 13 and the first communication hole 14, comes into contact with the inclined surface of the first inclined hole 15, and forms a space for rotational movement of fluid by the second spiral groove 27.

The second coupling piece 23 is a coupling member that protrudes from the other side of the second jet 21 and is fitted into the body portion 10, and is fitted into the first fitting hole 13. It is formed to protrude so as to extend outward on the other side of the second jetting body 21.

The second connection hole 24 is a connecting member formed on the other inside of the second jet 21 and connected to the socket portion 30, and is made of a hole formed inside the second coupling piece 23 and is coupled to the rear end. It is connected to communicate with the socket portion 30.

The second extension hole 25 is an extension member formed on the other inner side of the second injection body 21 and extending to be contracted to the second connection hole 24, and to be contracted to one end of the second connection hole 24. It extends to allow fluid to flow into the inner end of the second injection body 21.

The second communication hole 26 is a communication member formed through a plurality of penetrating elements around the outer periphery of the second extension hole 25 and communicating with the body portion 10. A plurality of second communication holes 26 are formed around the outer periphery of the second extension hole 25. It is formed radially spaced apart and communicates in the space between the first injection body 11 and the second injection body 21.

The second spiral groove 27 is a groove member formed in a plurality of helical depressions around the outer periphery of the second inclined piece 22. A plurality of second spiral grooves 27 are formed on the outer surface of the second inclined piece 22 and are curved toward the center. It consists of grooves spaced apart in a spiral shape and injects the fluid flowing into the space between the first injection body 11 and the second injection body 21 by forming the fluid into a rotating flow by these plurality of curved spiral grooves. do.

This second spiral groove 27 is composed of four orifices, and as shown in FIGS. 11 and 12, is spaced at a separation angle (θ ₁ ) of 30 to 40° with respect to the front portion of the second inclined piece 22. It is preferable that they are spaced apart and formed to be inclined at an inclination angle (θ ₂ ) of 40 to 50° along the inclined surface of the second inclined piece 22.

The socket portion 30 is a socket member that is coupled to the other inner side of the body portion 10 and connects it to a supply facility through which fluid flows. As shown in FIGS. 5 and 8, the socket 31 and the fitting piece 32 are , It consists of an inlet hole (33), a separation piece (34), and a separation groove (35).

The socket 31 is a socket member that is fitted and coupled to the other side of the body portion 10, and is coupled to the first fitting hole 13 of the first jet 11 to connect it to a supply facility through which fluid flows. .

The fitting piece 32 is a fitting member that protrudes from one end of the socket 31 and is fitted into the body portion 10. It is inserted into the first fitting hole 13 and connects one end of the first propellant 11. The socket 31 is fixed by fitting.

The inlet hole 33 is a hole member formed inside the socket 31 through which fluid flows. It is formed straightly in the longitudinal direction inside the socket 31 and communicates with a plurality of spaced grooves 35 on the outer circumference. This causes fluid to flow into the body portion 10 and the core portion 20.

The spacing piece 34 is a spacing member in which a plurality of spaced pieces protrude and are spaced apart from each other on the outer periphery of the socket 31 to form an inflow passage for fluid from the outside to the inside of the socket 31. It forms an inflow passage and supports the mesh portion 40 installed on the outside of the socket 31.

The spacing groove 35 is a groove member formed through the plurality of spacing pieces 34 to allow fluid to flow in. The spacing groove 35 is installed spaced apart between the plurality of spacing pieces 34 and penetrates to communicate with the inlet hole 33. It forms a fluid passage through which the fluid filtered by the mesh portion 40 flows.

The mesh portion 40 is a mesh member installed on the outer circumference of the socket portion 30 to filter the incoming fluid, and is installed to be supported on the outer circumference of the spacing piece 34 of the socket portion 30 ( 34) Foreign substances contained in the fluid flowing into the separation groove 35 formed between the fluids are filtered.

The cap portion 50 is a cover member that is fitted on one side of the outside of the body portion 10 and covers the body portion 10 to protect it, and is coupled to the tip of the first spray body 11 to form the first spray hole ( 17), the first injection hole 17 is covered to protect it from foreign substances entering the hole or from external shocks.

As explained above, according to the present invention, by providing a body part, a core part, and a socket part, the fluid is rotated and sprayed in a fog state to improve the spraying performance of the mist, and at the same time, the phenomenon of splashing, cracking, and tilting when spraying the mist is prevented. Provides an effect that can prevent.

In addition, the body part is provided with a first injection body, a first connection piece, a first fitting hole, a first communication hole, a first inclined hole, a first inlet hole, a first injection hole, and a first guide piece, so that the mist of the hydraulic body is provided. It improves particle injection performance, optimizes the size of the orifice to match the fluid particles and flow rate, maintains the quality of the nozzle due to sharp edges, and maintains the uniformity of the hollow cone pattern.

In addition, the core portion is provided with a second injection body, a second inclined piece, a second coupling piece, a second connection hole, a second extension hole, a second communication hole, and a second spiral groove, so that the fluid is discharged using four orifices. It provides the effect of improving the rotational force and optimizing the size and ratio of the spiral groove to improve the rotational force.

In addition, by providing a socket, a fitting piece, an inlet hole, a separation piece, and a separation groove as the socket portion, the connection between the body portion and the fluid supply facility can be facilitated and the fluid supply performance inside the body portion can be improved. Provides effect.

In addition, by further providing a mesh portion on the outside of the socket portion, foreign substances contained in the fluid supplied from the fluid supply facility are filtered out, thereby improving the mistization of the fluid and providing the effect of preventing contamination or clogging of the fluid passage. .

The present invention described above can be implemented in various other forms without departing from its technical idea or main features. Therefore, the above embodiment is merely an example in all respects and should not be construed as limited.

10: body part 20: core part
30: socket part 40: mesh part
50: cap part

Claims (5)

A mist spray nozzle that sprays fluid by rotating it,
A body portion 10 into which fluid flows and is sprayed;
A core portion (20) coupled to one inner side of the body portion (10), through which fluid is rotated and sprayed by spiral rotation; and
A mist spray nozzle comprising a socket portion (30) coupled to the other inner side of the body portion (10) and connected to a supply facility through which fluid flows. According to claim 1,
The body portion 10,
a first injection body to which the core portion 20 and the socket portion 30 are connected to allow fluid to flow;
A first connection piece installed around the other side of the first jet and connected to a supply facility through which fluid flows;
a first fitting hole formed inside the other side of the first jet, into which the socket portion 30 is fitted;
a first communication hole formed inside one side of the first injection body and coupled to communicate with the core portion 20;
a first inclined hole formed to be inclined at one end of the inner part of the first jet to obliquely move the fluid flowing in from the core portion 20;
a first inlet hole that is formed to be reduced at an inner end of the first jet and rotates the fluid flowing in from the core portion 20;
a first injection hole formed through an enlarged end of the first injection body to spray the fluid rotated in the core portion 20 in a fog state; and
A mist spray nozzle comprising a first guide piece that protrudes around the outer periphery of the first spray hole and guides the sprayed fluid in a mist state. According to claim 1,
The core portion 20,
a second jet that is fitted into one side of the body portion 10 and flows through the fluid through spiral rotation;
a second inclined piece formed to be inclined on one side of the second jet and inserted into the body portion 10;
a second coupling piece that protrudes from the other side of the second jet and is fitted into the body portion 10;
a second connection hole formed on the other side of the second injection body and connected to the socket portion 30;
a second extension hole formed on the other side of the second injection body and extending to be narrowed to the second connection hole;
a plurality of second communication holes formed around an outer periphery of the second extension hole and communicating with the body portion 10; and
A mist spray nozzle comprising a plurality of second spiral grooves formed in a spiral depression around the outer periphery of the second inclined piece. According to claim 1,
The socket portion 30 is,
A socket fitted into the other side of the body portion 10;
A fitting piece protruding from one end of the socket and fitted into the body portion 10;
an inlet hole formed inside the socket through which fluid flows;
A plurality of spaced pieces protrude and are spaced apart from each other around the outer periphery of the socket to form an inflow passage for fluid from the outside to the inside of the socket; and
A mist spray nozzle comprising a separation groove formed between the separation pieces and through which fluid flows. According to claim 1,
A mist spray nozzle further comprising a mesh portion (40) installed around the outer periphery of the socket portion (30) to filter the incoming fluid.

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