KR20160079428A - A Nozzle Assembly for Atomizing Liquid - Google Patents

Abstract

The present invention relates to a nozzle assembly for spraying a plurality of fluid particles and, particularly, to a nozzle assembly for spraying a plurality of fluid particles capable of spraying at least one gas and at least one liquid as a fluid particle type at the same time. The nozzle assembly for spraying the fluid particles comprises: a fluid supply body (11) wherein two or more inlets (112a, 112b) are formed; a fluid induction unit (12) which is connected to the fluid supply body (11) and forms a supply path capable of fluid transfer; a fluid transfer unit (13) which is connected to the fluid induction unit (12) and forms a path to induce a fluid inserted from the inlets (112a, 112b); an eddy generator (14) to form an eddy from the fluid induced from the fluid transfer unit (13); and a spray cap (15) to spray the fluid transferred from the fluid transfer unit (13) and the eddy generated in the eddy generator (14).

Description

[0001] The present invention relates to a nozzle assembly for atomizing liquid,

The present invention relates to a multiple fluid particulate spray nozzle assembly, and more particularly to a multiple fluid particulate spray nozzle assembly capable of simultaneously atomizing at least one gas and at least one liquid in particulate form.

The tube formed at the end of the flow path is referred to as a nozzle so that liquid or gas is ejected at high speed into the free space. Nozzles are known in the art to be designed to reach specific areas of solids, liquids, and gases in defined amounts and have various structures. For example, nozzles can be applied for surface coating in production processes of semiconductors, displays or mobile products. Semiconductors, displays, or mobile products are gradually changing to non-planar, aspherical, or three-dimensional shapes, fused with evolving technology in the field of materials. It is necessary that the ejection pressure or the amount of ejected liquid be accurately controlled in order to obtain a level of the coating surface required in the surface coating process of such a product. Also, the size of the particles in the coating process can be a major factor affecting the coating quality. For example, in order to form fine particles of 20 or less, it is necessary to adjust the nozzle diameter so as to correspond thereto. However, the smaller the nozzle diameter, the smaller the discharge pressure and the nozzle length may be limited. In order to solve such a problem, there is a demand for a nozzle having a required quality and a structural stability.

Prior Art No. 2005-0117416 discloses a two-fluid spray nozzle as a prior art related to a nozzle with respect to a nozzle. The prior art discloses a two fluid injection nozzle having a structure that allows the liquid to avoid contact with liquid and fixed walls so that the liquid does not have a velocity gradient due to friction with the fixed wall surface for fine and uniform sized spray. The prior art is a two fluid injection nozzle comprising: a housing constituting a body having a plurality of mixing holes formed at a lower end thereof; And an inner structure having a gas injection port which is inserted into a central portion of the housing to form a spacer between the housing and the compressor, and a liquid injection port which is coaxial with the mixing port and supplies the liquid to the mixing port, The present invention relates to a two-fluid injection nozzle including a plurality of fluid injection nozzles. The proposed prior art has a disadvantage in that the spacing of the spraying nozzles can be reduced by forming spacers in the spraying nozzles, but the spraying range can be reduced and clogging of the spraying nozzles can occur.

Another prior art related to nozzles is the No. 1363021 spray nozzle. The prior art is to provide a spray nozzle for generating particulates at low pressure and having a low scattering air curtain jetting function, comprising a first passage for supplying a first fluid, a second passage for supplying a second fluid, A first passage connected to the manifold and connected to the first passage to form a first discharge port and a second passage connected to the second passage with a first vortex groove outside the first discharge port; A first vortex, which is coupled to the manifold to receive the first vortex and connected to the second passage inward to form a second discharge port, and connected to the third passage with a second vortex groove outside the second discharge port And a discharge port which is in contact with the second vortex groove to receive the second vortex element and is connected to the manifold and connected to the third passage to form a third discharge port, Disclosed is an injection nozzle including a cap.

The proposed prior art has the disadvantage that the clogging phenomenon of the injection nozzle is solved, the uniformity of the sprayed fine particles and the injection structure of low pressure, but the diameter of the nozzle or the nozzle length can be limited. Further, the prior art or known nozzles are operated at a high pressure, and it is difficult to form uniform fine particles, and at the same time, it is difficult to atomize the liquid at a non-flow rate. On the other hand, a large number of fluids need to be sprayed through the nozzle assembly. For example, sterilization water needs to be sprayed by the nozzle assembly with other fluids for air purification. The prior art has the disadvantage that it is difficult to spray a large number of fluids.

The present invention is intended to solve the problems of known nozzles and has the following purpose.

Prior Art 1: Published Patent No. 2005-0117416 (published by Korea Institute of Energy Research, December 14, 2005) 2 Fluid injection nozzle Prior Art 2: Registration No. 1363021 (Innobis Co., Ltd., published Feb. 14, 2014) Spray nozzle

It is an object of the present invention to provide a nozzle assembly for multi-fluid particulate spray which is capable of operating at low pressures while allowing uniform microparticles to be formed and at the same time enabling the spraying of multiple fluids.

According to a preferred embodiment of the present invention, there is provided a fluid supply device comprising: a fluid supply body formed with at least two inflow passages; A fluid induction unit coupled to the fluid supply body and having a supply path through which fluid can be transferred; A fluid delivery unit coupled to the fluid induction unit and having a passage for guiding the fluid introduced from the at least two inflow passages; A vortex generator that forms a vortex from a fluid derived from the fluid transfer unit; And a spray cap for spraying a fluid transferred from the fluid induction unit and a vortex generated in the vortex generator.

According to another preferred embodiment of the present invention, further comprising a connection pad for leading the fluid supplied from the fluid supply body to the fluid transfer unit.

According to another preferred embodiment of the present invention, there is provided a fluid communication system comprising: a fluid communication unit for fluid communication between a fluid communication unit and a fluid communication unit, 2 connecting passages.

According to another preferred embodiment of the present invention, a vortex hole is formed so as to be connected to the vortex generator in the second connection passage.

According to another preferred embodiment of the present invention, there is further provided a spray hole formed in the center of the spray cap, wherein the spray hole is formed such that the fluid supplied from the two inlet passages is sprayed together in an annular shape along the circumferential surface .

According to another preferred embodiment of the present invention, the fluid in the vortex generator is directed along a slope.

The nozzle assembly according to the present invention primarily forms fine particles by collision of liquid and gas in a vortex generator, and forms secondary particles while being injected into an annular passage again. This allows fine particles to be formed at low pressure while simultaneously allowing the formation of fine particles for a large volume of liquid. Also, the nozzle assembly according to the present invention is applied as a nozzle for a gas cooling furnace and an air conditioner in a high-temperature combustion furnace to remove heavy metals such as NO _x , SO ₂ , mercury, arsenic or chromium. In addition, the nozzle assembly according to the present invention can be applied to a system for spraying a liquid mixed with an agent for ozone generation or deodorization, while being installed in a workplace or a plant facility so as to be applicable to the removal of noxious gases . In addition, the nozzle assembly according to the present invention allows air purification or removal of contaminants to be enhanced, for example by allowing fluid such as sterilization or ozonated water to be sprayed simultaneously with other fluids.

FIGS. 1A and 1B illustrate an embodiment of a multiple fluid particulate spray nozzle assembly according to the present invention.
2A and 2B illustrate an embodiment of each device applied to a nozzle assembly according to the present invention.
FIGS. 3A and 3B illustrate an operation of the nozzle assembly according to the present invention.

DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENTS Hereinafter, the present invention will be described in detail with reference to the embodiments shown in the accompanying drawings, but the present invention is not limited thereto. In the following description, components having the same reference numerals in different drawings have similar functions, so that they will not be described repeatedly unless necessary for an understanding of the invention, and the known components will be briefly described or omitted. However, It should not be understood as being excluded from the embodiment of Fig.

FIGS. 1A and 1B illustrate an embodiment of a multiple fluid particulate spray nozzle assembly according to the present invention.

Referring to FIGS. 1A and 1B, a multiple fluid particle spraying nozzle assembly 10 according to the present invention includes a fluid supply body 11 formed with at least two inflow passages 112a and 112b; A fluid induction unit (12) coupled to the fluid supply body (11), the fluid induction unit (12) having a supply path through which fluid can be transferred; A fluid transfer unit (13) coupled to the fluid induction unit (12) and provided with a passage for guiding the fluid introduced from the at least two inflow passages (112a, 112b); A vortex generator 14 that forms a vortex from the fluid derived from the fluid transfer unit 13; And a spray cap 15 for spraying the fluid transferred from the fluid guiding unit 12 and the vortex generated in the vortex generator 14.

The nozzle assembly 10 according to the present invention may be applied to or used with devices such as any air conditioners, dust collectors, dust collecting filters, or air circulation devices that purify the air by spraying the liquid in particulate form . Also, the nozzle assembly 10 according to the present invention can be applied to an apparatus such as a dispenser for coating or adhering by appropriate design changes. Therefore, the nozzle assembly 10 according to the present invention is not limited by the field of application.

The liquid sprayed through the nozzle assembly 10 according to the present invention may contain components for various types of sterilization or deodorization. In addition, the gas supplied through the nozzle assembly 10 may be part of indoor or outdoor air supplied or circulated through a separate supply device. The nozzle assembly 10 according to the present invention may be installed separately or used together with other devices, and may be applied to various types of liquid spraying, and is not limited by the type of fluid to be sprayed.

The fluid supply body 11 includes a supply body 111 having a cylindrical shape as a whole, first and second inflow passages 112a and 112b formed on both sides of the supply body 111, Hole 113, as shown in FIG. In this way, the fluid supply body 11 may have a T-type connection valve or connector structure, but the inlet passages 112a and 112b and the fastening hole 113 may be formed in various structures, and the present invention is not limited to the illustrated embodiment Do not. A first fluid such as a gas and a second fluid having different physical properties such as a liquid can be introduced through the first and second inflow passages 112a and 112b. The fluid transfer unit 13 may be connected to the fastening hole 113. A third fluid having properties different from those of the fluid supplied through the inlet passages 112a and 112b may be supplied through the fastening hole 113, for example. The third fluid can be the main component to be sprayed or coated and the third fluid supplied to the fluid transfer unit 13 is guided to the spray hole 152 formed in the spray cap 15 via an independent path . In the embodiment shown in FIGS. 1A and 1B, the first fluid may be a gas, the second fluid may be a liquid, and the third fluid may be a liquid, and the second fluid may be, for example, a fluid comprising a sterilizing component, And may be a liquid for improving physical properties. However, various types of fluids can be supplied through the first and second inflow passages 112a and 112b or the fluid transfer unit 13, and the present invention is not limited to the embodiments shown.

The first connection passage 114 may be formed in the first inlet passage 112a to guide the fluid introduced through the first inlet passage 112a to the fluid induction unit 12. [ And the second inlet passage 112b may be connected to the second connection passage 123 formed in the interior of the fluid induction unit 12. [

The first connection passage 114 may extend from the first inlet passage 112a perpendicularly to the circumferential surface and may be connected to the fluid induction unit 12 via the outside of the supply body 111. [ And the end portion of the second inflow passage 112b is connected to the guiding portion 127 formed in the lower portion of the fluid guiding unit 12 and the second connecting passage 123 is connected to the central portion of the fluid guiding unit 12 And may be formed along the circumferential surface of the fluid transfer unit 13. By such a path formation, the first fluid flows through the path formed along the circumferential surface of the fluid guiding unit 12, and the second fluid flows around the fluid transfer unit 13 passing through the fluid guiding unit 12, And may be directed to the spray cap 15 along a path formed along the central portion of the induction unit 12. And the first and second fluids and the third fluid transferred along the fluid transfer unit 13 may be led to the spray hole 152 along the respective independent transfer paths.

The fluid induction unit 12 includes an induction body 121 formed with a through path CP at a central portion thereof, a guide path 122 formed in the induction body 121, a second connection passage 123 formed along the through path CP, A swirl hole 124 for guiding the second fluid introduced from the second connection passage 123 to the swirl generator 14 and an induction tip 125 formed above the swirl hole 124. The connection pad 16 may be disposed between the supply body 111 and the fluid guiding unit 12 to guide the first fluid delivered to the first connection path 114 to the fluid guiding unit 12.

The induction body 121 may have various shapes that can be engaged with the supply body 111 and a through path CP through which the upper portion of the fluid transfer unit 13 is coupled may be formed at the center portion. The through path CP may be formed in a structure penetrating the upper part from the lower part of the induction body 121 and connected to the spray hole 152. The second connection passage 123 may be formed along the through path CP. The second connection passage 123 may be formed in the induction body 121 or may be formed using a coupling gap between the through passage CP and the fluid transfer unit 13. [ A vortex hole 124 for guiding the second fluid to the vortex generator 14 may be formed in the upper portion of the second connection passage 123. [ The vortex hole 124 may be formed in a direction perpendicular to the longitudinal direction of the second connection passage 123. The induction tip 125 formed in the upper portion of the vortex hole 124 may be made to form an inclined surface of the outer circumferential surface, but is not limited thereto and may have various structures that can induce the gas inside the vortex generator 14 . An end portion of the fluid transfer unit 13 may be disposed through the tip of the induction tip 125. [

The fluid transfer unit 13 for transferring the third fluid includes a transfer body 131 coupled to the supply body 111, a supply connector 132 formed inside the transfer body 131, And the first and second supply paths 133a and 133b for forming the supply path of the third fluid. The feed connector 132 may have any structure that can be coupled to various feed units for feeding a third fluid. The first and second supply paths 133a and 133b may have a tube shape having different cross-sectional areas and extending. For example, the first supply path 133a has a cross-sectional area corresponding to the supply connector 132, and the second supply path 133b has a cross-sectional area corresponding to the diameter of the spray hole 152. [ The supply amount of the fluid to be sprayed or the supply pressure of the first fluid such as the gas. Specifically, the second supply path 133b can be extended to reach the spray hole 152 with a predetermined length while having a diameter sufficiently smaller than that of the first supply path 133a. The second supply path 133b may be disposed in the through path CP described above and may extend through the spray tip to the spray hole 152. [

The vortex generator 14 may have a hollow cylindrical shape, an insertion hole 141 formed in a central portion of a lower surface thereof, and a cylindrical shape with an opened upper surface. A fluid guiding path 143 may be formed along the circumferential surface of the vortex generator 14 and a fluid guiding path 143 may be connected to the guiding path 122. The first fluid may be introduced through the first connection passage 114 and into the connection pad 16 and the induction path 122. The first fluid then flows into the vortex generator 14 through the fluid guiding path 143 and is guided into the spray hole 152 while forming a vortex with the fluid flowing through the second connection path 123 have.

The induction tip 125 of the induction cap may be disposed through the insertion hole 141 so as to pass through the inside of the vortex generator 14 and be positioned in front of the spray hole 152. A vortex hole 124 formed under the induction tip 125 is located inside the vortex generator 14 so that liquid can be introduced into the vortex generator 14. [ A sealing ring R may be disposed at a boundary surface between the vortex generator 14 and the induction cap so that the first fluid can be prevented from flowing into the vortex generator 14.

A vortex can be formed primarily as the liquid guided through the second connection path 123 is guided into the vortex generator 14 through the vortex hole 124. The fluid guided into the vortex generator 14 flows along the circumferential surface of the induction tip 125 while forming a vortex. Also, the first fluid introduced along the circumferential surface of the induction cap flows through the separation gap formed by the vortex generator 14 and the inner surface of the spray cap 15. The first fluid and the second fluid then meet at the end of the induction tip 125.

The spray cap 15 may consist of a hollow cylindrical induction housing 151 for allowing the vortex generator 14 to be received therein and a spray hole 152 formed on one side of the induction housing 151. One side of the induction housing 151 may be horn-shaped about the spray hole 152 and the other open side may be connected to the fluid induction unit 12 or fluid May be coupled to the supply body 11. The inner diameter of the spray hole 152 may be larger than the outer circumferential surface of the induction tip 125 so that a ring-shaped gap may be formed between the spray hole 152 and the induction tip 125 . The outer circumferential surface of the vortex generator 14 may have a smaller diameter than the inner circumferential surface of the induction housing 151, thereby forming a separation gap through which the first fluid can be guided.

The liquid sprayed through the spray hole 152 along the circumferential surface of the induction tip forming a vortex from the inside of the vortex generator 14 is guided through the separation gap and guided along one side of the inclined induction housing 151 The liquid supplied through the second supply path 133b can be sprayed in the form of fine particles through the end of the spray hole 152 or the second supply path 133b by the fluid that forms the second vortex. As described above, the nozzle assembly 10 according to the present invention is configured such that a vortex is formed first in the vortex generator 14 and then a vortex is formed secondarily by the gas induced along the circumferential surface of the vortex generator 14 So that the liquid sprayed through the second supply path 133b can be made into fine particles having a uniform diameter while simultaneously forming fine particles regardless of the amount of the liquid.

The supply paths 133a and 133b are extended with different diameters along the longitudinal direction and the spray cap 15 is moved in the longitudinal direction of the second supply path 133b or the fluid induction unit 12 The distance between the induction tip 125, the spray hole 152, and the second supply path 133b can be adjusted. For example, by adjusting the fastening of the fixing means B or by adjusting the level of engagement of the fluid transfer unit 13. [ And the amount of the liquid sprayed through the spray hole 152 or the average diameter of the fine particles can be appropriately adjusted by such an interval adjustment. It is possible to control the intervals of the fluid paths in which the spray holes 152 are formed in various ways, and the present invention is not limited to the embodiments shown.

As described above, the nozzle assembly 10 according to the present invention is configured such that uniform fine particles can be formed by applying a pressurized gas to generate fine particles while supplying fluid through three different paths, and at the same time, Thereby making it possible to atomize the liquid.

The first fluid corresponding to the pressurized gas is guided to the circumferential surface of the vortex generator 14 through the connection pad 16 and is accelerated by the rotation of the vortex generator 14. [ . The second fluid corresponding to the liquid is formed into a particulate form while being primarily vortically formed inside the vortex generator 14 and is discharged through the spray hole 152 together with the gas induced along the circumferential surface of the vortex generator 14 It can be made into fine particles by being sprayed in a ring shape or annular shape. At the same time, a strong shearing force is applied to the third fluid corresponding to the liquid supplied through the fluid transfer unit 13 to spray the particles in a particulate form. This enables the formation of fine particles having a uniform diameter by a low gas pressure, so that the power consumption of the compressor is reduced and the operation of the nozzle assembly 10 with the same compression performance is enabled.

Each device applied to the nozzle assembly 10 having such a structure will be described below.

2A and 2B illustrate an embodiment of each device applied to a nozzle assembly according to the present invention.

Referring to FIG. 2A, the fluid guiding unit 12 includes a coupling flange having a fixed plate 211 and an enclosed peripheral wall 212; A guide block 231 disposed in a central portion of the fixed plate 211 so as to have a substantially cylindrical shape and formed with an induction groove; A guide tube 25 forming a through path extending from the guide block 231 in a hollow cylindrical shape; And an induction tip 125 which forms an end of the induction tube 25. A vortex hole 124 may be formed under the induction tip 125 and connected to a second connection passage formed in the induction tube 25.

The fastening plate 211 may have any shape known in the art and the closed perimeter wall 212 may have an annular wall structure having a constant height and thickness. The guide block 231 may be formed to have a large height as compared with the closed peripheral wall 212 as a whole. At least one guide path 122 may be formed in a circular shape between the closed perimeter wall 212 and the guide block 231. The guide groove may be formed to be inclined with respect to the radial direction of the guide block 231 so that the width and depth of the guide block 231 may be reduced from the outer surface of the guide block 231, and a plurality of guide grooves may be formed along the circumferential direction. The guide groove can be connected to the fluid guide path formed on the circumferential surface of the vortex generator 14 and the pressurized gas introduced into the guide path 122 can be moved along the fluid guide path while forming a swirl at a high speed. The pressurized gas moved along the fluid guiding path can be guided to the spray hole along the inclined upper surface of the vortex generator 14. [

A plurality of vortex holes 124 may be formed along the circumferential surface of the induction tube 25 and may be connected to a second connection passage formed in the induction tube 25. Induction tip 125 may have the shape of a truncated cone. The shape of the truncated cone is such that the fluid is guided along the inclined surface to improve the shear force and uniform spraying of the fluid. The second supply path 133b may be arranged to pass through the through hole 222 passing through the induction tube 25 and the induction tip 125. [ The through hole 222 corresponds to the through path described above.

Referring to FIG. 2 (b), the connecting pad 16 may be in the form of an annular strip which is generally plate-shaped, and a plurality of induction holes 161 may be formed along the strip. The induction hole 161 can be connected to the first connection passage described above and to the induction path 122 formed in the fluid induction unit 12. [

2b, the vortex generator 14 includes an insertion hole 141 through which the induction tube 25 passes, and a vortex forming body 142 that forms a circular wall at the center of the insertion hole 141, And a fluid induction path 143 formed in the vortex forming body 142. [ The vortex-forming body 142 may form a circular wall structure having a uniform thickness and height as a whole. The fluid guiding path 143 can be made in the shape of a separation gap separating the circular wall into a plurality of pieces. The fluid guiding path 143 may be formed to extend from the outside of the vortex forming body 142 in an inclined direction with decreasing depth toward the inside. Due to this structure, the gas accelerates rapidly and forms a vortex and collides with the liquid.

2, the spray cap 15 includes an induction housing 151, an induction housing 151, and a spray hole 152 formed at an end portion of the induction housing. . The surface on which the spray hole 152 is formed may be an inclined surface and may be formed of a plurality of inclined surfaces having different inclination levels. For example, the circumferential surface adjacent to the spray hole 152 can be made annular so as to have a large inclination depending on the spraying range of the liquid, and the middle portion can have a small inclination Can be made. The large inclination refers to an angle with respect to the longitudinal direction of the induction housing 151.

A spray cap 15 having various shapes can be applied to the nozzle assembly 10 according to the present invention and the present invention is not limited to the embodiments shown.

The operation of the nozzle assembly 10 according to the present invention will be described below.

3A and 3B illustrate an embodiment of the operation of the nozzle assembly 10 according to the present invention.

3A and 3B, a first fluid GF, such as a gas, flows through the first inlet passage 112a and a second fluid LF1 such as a first liquid flows through the second inlet passage 112b. Lt; / RTI > And a third fluid LF2 such as a second liquid to be made into fine particles can be supplied through the first supply path 133a.

The first fluid GF may be introduced into the induction path 122 formed in the fluid induction unit 12 via the first connection passage 114 formed in the supply body 111 and the connection pad 16. The first fluid GF may then be directed into the spray hole 152 through the fluid induction path 143 formed in the vortex generator 14. [ The second fluid LF1 may be guided to the vortex hole 124 via the second connection passage 123 formed in the fluid induction unit 12 and transferred to the vortex generator 14. [ And then introduced into the spray hole 152 together with the first fluid GF in the vortex generator 14.

The third fluid LF2 may be led to the spray hole 152 via the first supply path 133a and the second supply path 133b. The third fluid LF2 is sprayed through the spray hole 152 into the form of a vortex so that the first fluid LF1 and the second fluid LF2, which are annularly sprayed through the spray hole 152 along the upper inclined surface of the spray tip, Lt; RTI ID = 0.0 > shear < / RTI > Thereby, the third fluid LF2 can be sprayed with uniform fine particles.

The nozzle assembly 10 according to the present invention allows various fluids to be uniformly sprayed in particulate form and the present invention is not limited to the embodiments shown.

The liquid atomizing nozzle assembly 10 according to the present invention firstly forms fine particles by collision between liquid and gas in the vortex generator 14, and forms secondary particles while being injected into the annular passage again. This allows fine particles to be formed at low pressure while simultaneously allowing the formation of fine particles for a large volume of liquid. Further, the liquid atomizing nozzle assembly according to the present invention is applied as a nozzle for a gas cooling and an air conditioner in a high-temperature combustion furnace to remove heavy metals such as NO _x , SO ₂ , mercury, arsenic or chromium. In addition, the nozzle assembly according to the present invention can be applied to a system for spraying a liquid mixed with an agent for ozone generation or deodorization, while being installed in a workplace or a plant facility so as to be applicable to the removal of noxious gases . In addition, the nozzle assembly according to the present invention allows air purification or removal of contaminants to be enhanced, for example by allowing fluid such as sterilization or ozonated water to be sprayed simultaneously with other fluids.

While the present invention has been particularly shown and described with reference to exemplary embodiments thereof, it will be understood by those of ordinary skill in the art that various changes in form and details may be made therein without departing from the spirit and scope of the invention . The invention is not limited by these variations and modifications, but is limited only by the claims appended hereto.

10: nozzle assembly 11: fluid supply body
111: supply body 112a, 112b: first and second inflow passages
113: fastening hole 114: first connection passage
12: fluid induction unit 121: induction body
122: guide path 123: second connection passage
124: vortex hole 125: induction tip
127:
13: Fluid feed unit 131: Feed body
132: supply connector 133a, 133b: first and second supply paths
14: vortex generator 141: insertion hole
142: vortex forming body 143: fluid induction path
15: Spray cap 151: Induction housing
152: spray hole 153: accommodation space
16: connection pad 161: guide hole
221: Fixing plate 212: Closed perimeter wall
222: through hole 231: guide block
25: induction tube

Claims (6)

A fluid supply body (11) formed with at least two inlet passages (112a, 112b);
A fluid induction unit (12) coupled to the fluid supply body (11), the fluid induction unit (12) having a supply path through which fluid can be transferred;
A fluid transfer unit (13) coupled to the fluid induction unit (12) and provided with a passage for guiding the fluid introduced from the at least two inflow passages (112a, 112b);
A vortex generator 14 that forms a vortex from the fluid derived from the fluid transfer unit 13; And
And a spray cap (15) for spraying the fluid transferred from the fluid guiding unit (12) and the vortex generated in the vortex generator (14). The nozzle assembly of claim 1, further comprising a connection pad (16) for guiding the fluid supplied from the fluid supply body (11) to the fluid transfer unit (13). The fluid supply apparatus according to claim 1, further comprising a fluid supply unit (112) for connecting one of the at least one inflow passage (112a) to the first connection passage (114) Further comprising a second connection passage (123) formed around the unit (13). 4. The nozzle assembly as claimed in claim 3, wherein a vortex hole (124) is formed in the second connection passage (123) so as to be connected to the vortex generator (14). The apparatus of claim 1, further comprising a spray hole (152) formed in the center of the spray cap (15), wherein the spray hole (152) Wherein the fluid is configured to be sprayed together. ≪ Desc / Clms Page number 18 > The nozzle assembly of claim 1, wherein the fluid in the vortex generator (14) is directed along an inclined plane.

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