KR102409264B1 - High elevation fountain nozzle - Google Patents

Abstract

A nozzle part that ejects water through an open outlet at the tip with a hollow tube structure extending in the axial direction and having an empty inside so as to save energy while reducing scattering and increasing the spray height of water; and an air supply unit disposed along the direction to eject air to the center of the water sprayed from the nozzle unit, wherein the nozzle unit protrudes toward the center on the inner surface, extends along the axial direction, and is arranged at intervals along the circumferential direction. It further includes four guide ribs to provide a dead spray nozzle having a structure for guiding the flow of water introduced into the nozzle unit in an axial direction.

Description

Dead sand spray nozzle {HIGH ELEVATION FOUNTAIN NOZZLE}

The present disclosure relates to dead spray nozzles.

In general, a fountain is to make a water gutter in a garden, park, or public plaza and spout water so that you can feel the cool sensation along with its dynamic beauty. The fountain has a structure in which water is compressed by sucking in the centrifugal force of the pump, and the compressed water to have a predetermined pressure is ejected through a nozzle provided at the end of the pipe.

The nozzle used in the fountain device converts pressure energy into velocity energy by reducing the ejection cross-sectional area when ejecting high-pressure liquid. Such a nozzle has disadvantages in that it is difficult to finely adjust the spray height of water only by the power of the pump, and colorless water is sprayed so that it is not conspicuous.

Accordingly, the present applicant has improved the structure of the conventional dead water fountain nozzle to develop a dead water fountain nozzle that sprays water together with air at a high pressure. Korean Patent Registration No. 10-0487892 discloses a dead fountain nozzle developed and patented by the present applicant. In the dead fountain nozzle, the water discharged from the pump is sprayed at high pressure in a mixed state with air, so that the height of the fountain can be increased, the shape of the fountain is bright and beautiful in white, and the spraying fountain is also produced. The height and thickness can be easily adjusted.

In recent years, as the number of attractions increases, the demand for more visually gorgeous fountains is increasing. Accordingly, in response to these needs and the highly exchanged market environment, it provides many advantages to users to provide improved and improved existing dead fountain nozzles.

An object of the present invention is to provide a dead spray nozzle capable of spraying with less scattering and higher.

An object of the present invention is to provide a dead jet nozzle capable of preventing vortex generation.

An object of the present invention is to provide a dead spray nozzle capable of preventing the sprayed water from being disturbed.

An object of the present invention is to provide a dead spray nozzle capable of spraying water with less energy.

The dead fountain nozzle of this embodiment has a hollow tubular structure extending in the axial direction and ejecting water through an open outlet at the tip end, and is disposed along the axial direction in the inner center of the nozzle unit, the nozzle unit It may include an air supply for ejecting air to the center of the water sprayed from.

The nozzle unit may include an upper body and a lower body that are disposed vertically and are detachably installed, and may have a structure in which an inner diameter gradually decreases toward an outlet at the upper end.

The nozzle part protrudes toward the center on the inner surface, extends along the axial direction, and further includes a plurality of guide ribs arranged at intervals along the circumferential direction, so as to guide the flow of water introduced into the nozzle part in the axial direction. have.

The guide rib may be formed on the lower body and/or the upper body of the nozzle unit.

The air supply unit is disposed at the inner center of the lower body of the nozzle unit and is connected to an inlet formed on the side of the lower body to receive external air, is connected to the upper end of the inlet pipe and extends to the upper outlet of the upper body, so that air The discharge pipe may include a cap disposed inside the upper end of the discharge pipe and forming a gap at a predetermined interval so that air is ejected between the discharge pipe and the inner circumferential surface of the discharge pipe.

The air supply unit has a fixing member installed on the inner surface of the discharge pipe via an arm and is disposed in the center of the discharge pipe, and a female screw hole for bolting is formed in the fixing member, so that the cap is installed on the fixing member by a bolt. can

The nozzle may further include a flow stabilizing unit provided at an upper end of the nozzle unit to stably guide the flow of the sprayed water.

The flow stabilizing part extends from the upper end of the upper body in a straight line toward the upper part and has a constant inner diameter along the axial direction. It may include a formed extension tube portion, the side of the cap extending to the height of the upper end of the extension tube portion, the diameter of the side surface may be formed to be constant.

The interval between the extended body and the extended pipe from which water is sprayed from the flow stabilizing unit may be constant along the axial direction, and the interval between the extended pipe through which air is ejected and the side surface of the cap may have a constant structure along the axial direction.

The axial length of the flow stabilizing part may be 0.12 to 0.14 times the axial length of the nozzle part.

According to the present embodiment, the flow of water and air ejected from the tip of the nozzle is more stabilized to prevent disturbance of water.

By guiding the flow of water inside the nozzle, it is possible to minimize the occurrence of water vortices.

Accordingly, compared to the conventional fountain, energy can be saved while scattering is small and the spray height of water can be increased.

1 is a perspective view of the dead fountain nozzle according to the present embodiment.
2 is an exploded perspective view of the dead fountain nozzle according to the present embodiment.
3 is a cross-sectional view of the dead fountain nozzle according to the present embodiment.
4 is a cross-sectional view taken along line AA of FIG. 3 .
5 and 6 are partially cutaway perspective views showing the cap of the dead fountain nozzle according to the present embodiment.

Hereinafter, embodiments of the present invention will be described in detail. However, this is provided as an example, and the present invention is not limited thereto, and the present invention is only defined by the scope of the claims to be described later. The embodiments to be described below may be modified in various forms without departing from the concept and scope of the present invention. Wherever possible, identical or similar parts are denoted by the same reference numerals in the drawings.

The terminology used below is for the purpose of referring to specific embodiments only, and is not intended to limit the present invention. As used herein, the singular forms also include the plural forms unless the phrases clearly indicate the opposite. The meaning of "comprising," as used herein, specifies a particular characteristic, region, integer, step, operation, element and/or component, and other specific characteristic, region, integer, step, operation, element, component, and/or group. It does not exclude the existence or addition of

1 shows the external appearance of the dead fountain nozzle according to the present embodiment, and FIGS. 2 and 3 show the configuration of the dead fountain nozzle.

In the following description, the axial direction means the y-axis direction in FIG. 1 in a direction through which the central axis of the tube structure passes. In addition, when the nozzle outlet is directed upward, the upper direction along the y-axis direction is referred to as the upper, upper, and upper direction, and the opposite direction is referred to as the lower, lower, and lower direction.

As shown, the dead fountain nozzle 100 of this embodiment has a hollow tube structure extending in the axial direction and ejecting water through an open outlet 16 at the tip of the nozzle 10, the nozzle The air supply unit 20 disposed in the inner center of the unit 10 along the axial direction to eject air to the center of the water sprayed from the nozzle unit 10, and provided at the top of the nozzle unit 10 to stably control the flow of water to be sprayed It may include a flow stabilizing unit 50 to induce.

As water is sprayed from the nozzle part 10 , the air introduced through the air supply part 20 is ejected into the water sprayed from the nozzle part 10 to form an air wall. Therefore, the water stream is not dispersed by the air ejected to the center of the stream, and the fountain can rise high while forming white foam.

In addition, the disturbance of the water sprayed from the nozzle by the flow stabilizing unit 50 can be further prevented. Accordingly, the scattering of water is suppressed, so that water can be sprayed more stably and higher even with a small amount of energy.

The nozzle unit 10 may include an upper body 12 and a lower body 14 that are vertically disposed and detachably installed. The lower body 14 is coupled to the upper end of the lower body 14 .

The upper body 12 and the lower body 14 may be hollow tubular structures with an empty interior. The upper body 12 and the lower body 14 may be formed in a cone structure whose inner diameter decreases toward the upper portion. The upper body 12 is coupled to the open upper end of the lower body 14 .

The upper body 12 is coupled to the upper end of the lower body 14 to communicate with the lower body 14, and the upper end is opened to form an outlet 16 through which water is sprayed.

A flange 13 having a through hole for fastening with each other may be formed at the junction of the upper body 12 and the lower body 14 . Accordingly, the flange 13 provided at the lower end of the upper body 12 is buttted to the flange 13 of the upper end of the lower body 14, and then the bolt and the nut are fastened through the through hole to the lower body 14 and the upper body. (12) can be assembled.

The lower body 14 is connected to the outlet side of the pump, for example. Accordingly, the high-pressure water supplied through the pump flows into the nozzle unit 10 through the lower end of the lower body 14 and is sprayed upward through the upper outlet 16 of the upper body 12 installed in the lower body 14 . do.

The nozzle unit 10 has a structure in which the internal cross-sectional area becomes smaller as it goes upward, and the water introduced into the nozzle unit 10 is further compressed while moving upward and is sprayed at high pressure through the outlet 16 at the tip of the nozzle unit 10 . can be

In the process in which water is sprayed at high pressure from the nozzle unit 10 , external air is introduced through the air supply unit 20 and is ejected upward through the upper part of the nozzle unit 10 .

The air supply unit 20 moves the air introduced from the outside of the nozzle unit 10 to the upper end of the upper body 12 and supplies it to the inner surface of the sprayed water to form an air wall. As noted here, the water rises higher by the central air wall, forming a foam by the air ejected together. Accordingly, the water sprayed from the nozzle unit 10 rises high in white foam and is easily visible to the eyes of a distant visitor.

The air supply unit 20 of the present embodiment is disposed in the inner center of the lower body 14 of the nozzle unit 10 and is connected to the inlet 21 formed on the side of the lower body 14, the inlet pipe 22 through which external air is introduced. , the discharge pipe 24, which is connected to the upper end of the inlet pipe 22 and extends to the upper outlet 16 of the upper body 12, through which air is discharged, is disposed inside the upper end of the discharge pipe 24 and the inner circumferential surface of the discharge pipe 24 It may include a cap 30 that forms a gap at a predetermined interval so that air is ejected between the fruit.

The inlet pipe 22 may be integrally formed with the lower body 14 . The inlet pipe 22 is a pipe structure to allow air to flow therein, and is disposed in the axial direction at the center of the lower body 14 . A connecting passage 23 is formed between the lower side of the inlet pipe 22 and the inlet 21 formed in the lower body 14 to be connected to each other. Accordingly, the air outside the nozzle unit 10 may be introduced into the inlet pipe 22 connected to the connection passage 23 through the inlet 21 . The connection passage 23 may act as a support structure for fixing the inlet pipe 22 to the central portion with respect to the lower body 14 .

The connection passage 23 may have a streamlined cross-sectional shape elongated along the flow direction of water. In addition, the connection passage 23 may be formed to be inclined upward from the inlet 21 toward the inlet pipe 22 . Accordingly, it is possible to minimize the action of the connection passage 23 as a resistance to the water flowing along the inside of the lower body 14.

At least one inlet 21 may be formed along the outer periphery of the lower body 14 . Each inlet 21 may be connected to the inlet pipe 22 through a separate supply line. In addition, a filter (not shown) for preventing the inflow of foreign substances may be further installed in the inlet 21 . Accordingly, it is possible to prevent foreign substances from being introduced into the inlet pipe 22 through the inlet 21 from the outside while the fountain is being operated.

The water supplied into the lower body 14 may be transferred upward through the space between the inlet pipe 22 and the inner surface of the lower body 14 .

The inlet pipe 22 may be formed at about the same height as the upper end of the lower body 14 . The discharge pipe 24 is connected to the open upper end of the inlet pipe 22 and installed. The discharge pipe 24 may be installed by being screwed to the inflow pipe 22 . A packing 25 for sealing may be further installed between the inlet pipe 22 and the discharge pipe 24 .

The discharge pipe 24 communicates with the inlet pipe 22 as an elongated pipe structure. The discharge pipe 24 is disposed in the axial direction at the center of the upper body 12 . Air from the inlet pipe 22 to the inlet pipe 22 is blown out through the open top of the outlet pipe 24 .

The upper end of the discharge pipe 24 may be formed at the same height as the upper outlet 16 of the upper body 12 .

A gap between the discharge pipe 24 and the upper end of the upper body 12 forms an outlet 16 through which water is discharged. Accordingly, the water supplied to the nozzle unit 10 is compressed while moving over the upper body 12 and is sprayed at high pressure through a gap between the discharge pipe 24 , which is the outlet 16 , and the inner surface of the upper body 12 .

In the present embodiment, the discharge pipe 24 may have a structure in which the inner diameter and the outer diameter gradually increase toward the top. Accordingly, water can be further compressed by reducing the cross-sectional area between the discharge pipe 24 and the upper body 12 in addition to the upper body 12 toward the upper part. In addition, the internal cross-sectional area of the discharge pipe 24 through which air flows is expanded toward the upper part, thereby increasing the air flow rate.

A cap 30 for ejecting air is installed at the upper end of the discharge pipe 24 .

The cap 30 may be fixedly installed to the fixing member 26 installed in the discharge pipe 24 via the bolt 27 . A hole 31 for fastening the bolt 27 is formed at the lower end of the central portion of the cap 30 . The fixing member 26 is installed on the inner surface of the discharge pipe 24 via the arm 28 and is disposed in the center of the discharge pipe 24 . A female screw hole for bolting is formed in the fixing member 26 . Accordingly, the cap 30 may be installed on the fixing member 26 by the bolts 27 .

The cap 30 is a circular structure, and the lower end may form an arc shape so that air flows smoothly. The diameter of the cap 30 is formed to be smaller than the inner diameter of the discharge pipe 24 . Accordingly, a gap is formed in a circular shape between the inner surface of the discharge pipe 24 and the cap 30 . This gap forms the upper end outlet 29 of the discharge pipe 24 for blowing out air. The air introduced into the discharge pipe 24 is ejected upward through a gap serving as the outlet 29 . Accordingly, air is blown out in a circular ring shape having a uniform pressure by the cap 30 installed on the discharge pipe 24 . As air is ejected from the upper outlet of the discharge pipe 24, an air wall in the form of a tube is formed in the center of the water.

In this embodiment, the nozzle unit 10 may further include a plurality of guide ribs 18 installed on the inner surface.

As shown in FIG. 4 , the guide rib 18 is a plate structure having a thin thickness, and may be formed to protrude from the inner surface toward the center. The guide ribs 18 may be arranged at intervals along the circumferential direction of the nozzle unit 10 . Each of the guide ribs 18 extends along the axial direction in which the water moves to guide the water.

Accordingly, by guiding the flow of water introduced into the nozzle unit 10 in the axial direction, it is possible to prevent a vortex from being formed in the nozzle unit 10 .

The number of guide ribs 18 formed may be variously modified and is not particularly limited.

In this embodiment, the guide rib 18 may be formed on the lower body 14 . The guide rib 18 may be integrally formed with the lower body 14 . The lower body 14 is a structure having a relatively larger diameter compared to the upper body 12, and the guide rib 18 can be more easily formed.

In addition to the above structure, a structure in which a guide rib is provided inside the lower body by fixing and installing a separate cylindrical structure in which the guide rib is formed on the inner surface of the lower body may also be applied.

As is known, the high-pressure water supplied from the pump is introduced into the lower end of the nozzle unit 10 to cause a vortex. That is, the water supplied to the lower body 14 is supplied while swirling in the form of a vortex to move upward.

The guide rib 18 formed on the lower body 14 induces water in the axial direction while preventing the vortex of the water supplied in the form of a vortex.

Accordingly, water stably flows upward along the axial direction by the guide rib 18 . Accordingly, it is possible to prevent energy loss of water due to the vortex, and to spray water through the outlet 29 at a higher pressure, and to spray water higher even with the same energy. On the other hand, in the case of the related art, as the water moves in the axial direction of the nozzle unit 10 in a vortex state, a loss of compressive force occurs, and it is difficult to increase the spray height of water with little power.

In another embodiment, the guide rib may be formed on the upper body as well as the lower body. The guide ribs formed on the upper body may be formed at positions corresponding to the guide ribs formed on the lower body and connected to each other. Accordingly, in the case of this structure, the guide rib is formed to extend from the lower part to the upper part of the nozzle part as a whole including the upper body and the lower body, so that water can be stably guided to the upper part. Accordingly, the effect of preventing the vortex of water can be further enhanced.

In addition, the nozzle of this embodiment is further provided with a flow stabilizing unit 50 on the upper portion of the nozzle unit 10, thereby preventing the disturbance of water through the flow stabilizing unit 50, thereby stably maintaining the shape of the fountain.

To this end, the flow stabilizing part 50 extends from the upper end of the upper body 12 to the upper part in a straight line, the extended body 51 having a constant inner diameter along the axial direction, and the discharge pipe 24 are straight from the upper end to the upper part. It extends to and includes an extension tube portion 52 having an outer diameter and an inner diameter uniformly formed along the axial direction. In addition, the cap 30 may have a structure in which the side surface 32 extends to a height of the upper end of the extension tube portion 52 , and the diameter of the side surface 32 is constant.

The height of the upper end of the extended body 51 of the flow stabilizing unit 50, the extended pipe unit 52, and the side surface 32 of the cap 30 may have the same structure.

5 shows a cap 30 according to the present embodiment.

As shown, the cap 30 includes vertically extending sides 32 . The side surface 32 may be integrally formed with the cap 30 . The top height of the side surface 32 may be formed to correspond to the top height of the flow stabilizing unit 50 . The side surface 32 has a cylindrical shape and is formed with the same outer diameter along the axial direction. Accordingly, the air may be stably discharged and ejected.

6 shows a cap 30 of another embodiment. The cap 30 shown in FIG. 6 has a structure in which a plurality of guide blades 34 are arranged in a radial direction at the lower portion. Except that the guide blade 34 is further provided, the other structure is the same as the cap described above. By further forming the guide blades 34 under the cap 30, it is possible to induce air to flow more smoothly toward the outlet. Accordingly, it is possible to further stabilize the flow of air.

The extended body 51 and the extended pipe part 52 may be integrally formed with the upper body 12 and the discharge pipe 24, respectively.

The flow stabilizing part 50 communicates with the outlet 16 of the nozzle part 10 between the extended body 51 and the extended pipe part 52 along the axial direction to form a pipe 53 through which water is sprayed.

Water sprayed at high pressure from the outlet 16 of the nozzle unit 10 passes through the pipe line 53 between the extended body 51 and the extended pipe unit 52 of the flow stabilizing unit 50 connected to the outlet 16 and is sprayed upward. .

The interval C of the pipe 53 between the extended body 51 and the extended pipe 52 to which water is sprayed from the flow stabilizing part 50 of this embodiment is constant along the axial direction. Accordingly, the flow of water may be stabilized while passing through the conduit 53 between the extended body 51 and the extended pipe portion 52 . Accordingly, the disturbance of the water is minimized so that the water can be sprayed straight upward. Therefore, it becomes possible to raise the spray height of water more.

In the flow stabilizing part 50, a conduit 54 through which air is injected is formed between the extended pipe part 52 and the side surface 32 of the cap 30 along the axial direction in communication with the outlet of the air supply part 20.

Air ejected from the outlet of the discharge pipe 24 of the air supply unit 20 is a pipe 54 between the extension pipe 52 of the flow stabilizing unit 50 connected to the outlet 29 and the side 32 of the cap 30. It passes through and is ejected upward.

The interval (R) of the conduit 54 between the side surface 32 of the cap 30 and the extended pipe part 52 through which air is ejected from the flow stabilizing part 50 of this embodiment is constant along the axial direction. Accordingly, the flow of air may be stabilized while passing through the conduit 54 between the extension conduit and the side surface 32 of the cap 30 . Accordingly, the disturbance of the air is minimized, so that the air wall can be stably formed in the water by the air. With this stable air wall formation, water can be sprayed higher while maintaining its shape.

In this way, the water and air discharged from the nozzle unit 10 and the air supply unit 20 are sprayed through the elongated flow stabilizing unit 50, and can be sprayed higher while stably maintaining the shape of the water.

In this embodiment, the axial length (D) of the flow stabilizing unit 50 may be 0.12 to 0.14 times the axial length (L) of the nozzle unit (10). The axial length D of the flow stabilizing part 50 may mean a length from the top of the nozzle part 10 to the top of the flow stabilizing part 50 .

When the ratio of the axial length (D) of the flow stabilizing part 50 is smaller than the above range, the stabilizing effect of water and air does not appear. When the ratio of the axial length (D) of the flow stabilizing part 50 is greater than the above range, a problem in which the spray height of water is reduced rather occurs.

Hereinafter, the operation of the present embodiment will be described as follows.

When the pump is operated, the water introduced into the lower body through the pump and the pipe moves directly upward along the axial direction while the vortex is prevented by the guide rib 18 provided inside the nozzle unit 10 .

Water is sprayed upward through the conduit 53 of the flow stabilization unit 50 through the outlet 16 of the nozzle unit 10 in a compressed state while moving upward.

At the same time, the air introduced through the inlet 21 of the air supply unit 20 flows through the outlet 29 between the outer surface 32 of the cap 30 and the inner surface of the discharge pipe 24 through the flow stabilizing unit 50 ) through the conduit 54 and is ejected upward. As the air forms an air film inside the water, the stream rises straight up.

And as the stream mixes with water in a small amount on the way up, it changes the refractive index and is reflected in white, making it clearly visible even from a distance.

In this process, the flow of water and air is stabilized as it passes through the flow stabilizing unit 50 in communication with the outlet of the nozzle unit 10 and the air supply unit 20 . Accordingly, the shape of the water is stably maintained so that it can be sprayed higher. Therefore, it is possible to produce a fountain of the same height even with a smaller lift and provision, thereby reducing operating costs.

As described above, although exemplary embodiments of the present invention have been illustrated and described, various modifications and other embodiments may be made by those skilled in the art. All such modifications and other embodiments are intended to be contemplated and included in the appended claims without departing from the true spirit and scope of the present invention.

10: nozzle unit 12: upper body
14: lower body 16,29: exit
18: guide rib 20: air supply unit
21: inlet 22: inlet pipe
23: connection passage 24: discharge pipe
26: fixing member 30: cap
32: side 34: guide collar
50: flow stabilization unit 51: extended body
52: extension pipe 53,54: pipe
100: nozzle

Claims (4)

A nozzle unit that ejects water through an open outlet at the tip in a hollow tube structure extending in the axial direction and hollow inside, disposed along the axial direction in the inner center of the nozzle unit to supply air to the center of the water sprayed from the nozzle unit Including an air supply unit that ejects,
The nozzle unit includes an upper body and a lower body that are disposed and detachably installed in the top and bottom, and the nozzle unit protrudes toward the center on the inner surface, extends along the axial direction, and a plurality of guides arranged at intervals along the circumferential direction. It is a structure that further includes a rib to guide the flow of water introduced into the nozzle unit in the axial direction,
The air supply unit is disposed at the inner center of the lower body of the nozzle unit and is connected to an inlet formed on the side of the lower body to receive external air, is connected to the upper end of the inlet pipe and extends to the upper outlet of the upper body, so that air a discharge pipe to be discharged, and a cap disposed inside the upper end of the discharge pipe and forming a gap at a predetermined interval so that air is blown out between the discharge pipe and an inner peripheral surface of the discharge pipe;
Further comprising a flow stabilizing unit provided at the top of the nozzle unit to stably guide the flow of the sprayed water,
The flow stabilizing part extends from the upper end of the upper body in a straight line toward the upper part and has a constant inner diameter along the axial direction. Including an extended pipe portion formed, the side of the cap extends to the upper end of the extended pipe portion, the diameter of the side is formed to be constant, the distance between the extended body and the extended pipe portion to which water is sprayed from the flow stabilizing unit is an axis A dead spray nozzle having a structure constant along the direction, and a distance between the extended pipe portion and the side surface of the cap through which air is sprayed is constant along the axial direction. delete delete delete

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