KR101450235B1 - Fountain nozzle assembly - Google Patents

Abstract

The present invention relates to a fountain nozzle assembly, comprising: a fountain nozzle having a fraction discharge space; A tubular body coupled to the fractional nozzle at one side in the lengthwise direction and transferring water supplied from the outside to the fractional discharge space of the fractional nozzle; A guide plunger accommodated in the tube and reciprocatingly moved toward and away from the fractional nozzle according to the supply of the water; An optical fiber extending to the fractional discharge space through the tubular body and having one longitudinal direction region fixed to the guide plunger so that a distal end portion of the optical fiber enters and exits the inside and the outside of the fractional discharge space according to reciprocal movement of the guide plunger; And a light source that transmits light to the optical fiber.
Thereby, there is provided a fountain nozzle assembly that can maximize aesthetic effects by providing differentiated sights and aesthetics.
A fountain nozzle assembly is also provided that includes a lighting function and does not hinder the appearance of the fountain facility without the use of fractions.

Description

[0001] FOUNTAIN NOZZLE ASSEMBLY [0002]

The present invention relates to a fountain nozzle assembly, and more particularly, to a fountain nozzle assembly that has a fountain function and an illumination function using an optical fiber to provide differentiated sights and aesthetics, thereby maximizing aesthetic effects. The fountain nozzle assembly does not hinder the appearance of the fountain facility by being exposed to the outside.

Fountains constructed for decorative purposes in parks, gardens, squares, or indoors have a form in which the water pumped by the pump is delivered to the fountain nozzles through the pipeline and is discharged with a strong pressure from the fountain nozzles.

Among these, a fountain nozzle typically has a nozzle hole for discharging the water supplied therein with a strong pressure, and has a discharge space and a discharge port that can control the direction and the shape of the water discharged to the nozzle hole.

However, such a conventional fountain nozzle simply provides aesthetic effects such as sights and aesthetics due to the direction of discharge of water and deformation of the shape, and does not provide the aesthetic effect of the fountain nozzle itself at night.

Accordingly, it has been common to provide an illumination to the water in the fraction, to illuminate the water discharged from the water nozzle, thereby giving an aesthetic effect to the water at night.

However, there has been a problem that the aesthetic effect to such a degree of illuminating such a light to the discharged water has a limitation in producing a different aesthetic effect as a general fountain lighting effect.

In addition, since the lights are directly exposed to the outside of the fountain, when the fountain is not used, complicated lighting devices are exposed to the outside, which hinders the appearance of the fountain facility.

Accordingly, it is an object of the present invention to provide a fountain nozzle assembly capable of maximizing aesthetic effects by providing differentiated sights and aesthetics.

It is also an object of the present invention to provide a fountain nozzle assembly that does not hinder the appearance of a fountain facility without the use of fractions, including lighting functions.

This object is achieved according to the present invention by a fountain nozzle assembly comprising: a fountain nozzle having a fractional discharge space; A tubular body to which the fractional nozzle is coupled at one side in the longitudinal direction and to transfer water supplied from the outside to the fractional discharge space of the fractional nozzle; A guide plunger accommodated in the tube and reciprocatingly moved toward and away from the fractional nozzle according to the supply of the water; An optical fiber extending to the fractional discharge space through the tubular body and having one longitudinal direction region fixed to the guide plunger so that a distal end portion of the optical fiber enters and exits the inside and the outside of the fractional discharge space according to reciprocal movement of the guide plunger; And a light source for transmitting light to the optical fiber.

Here, the entrance of the fractional discharge space is preferably provided with an optical fiber entrance guider for guiding the entrance and exit of the optical fiber.

At this time, it is effective that the optical fiber entrance guider has a discharge port formed at the central portion thereof, and an optical fiber guide hole through which the optical fiber passes is formed in the peripheral region.

In addition, it is preferable that the optical fiber is provided in a plurality of strands, and the optical fiber guide hole is formed in a number corresponding to the number of strands of the optical fiber.

On the other hand, it is more effective that a nozzle hole through which the water is discharged and an optical fiber through hole through which the optical fiber passes are formed at the bottom of the fractional discharge space.

Preferably, the guide plunger is formed with an optical fiber fixing hole to which the optical fiber is fixed, and a water passage hole through which the water passes.

Further, an airtight cap is coupled to the other longitudinal side of the tubular body, and the optical fiber extends outwardly through the airtight cap. It is effective that a water inflow hole through which the water is supplied from outside is formed in a peripheral region of the tube adjacent to the airtight cap.

Preferably, the light source is an LED that transmits light to an extending end of the optical fiber extending outward.

According to the present invention, there is provided a fountain nozzle assembly capable of maximizing aesthetic effects by providing differentiated sights and aesthetics.

A fountain nozzle assembly is also provided that includes a lighting function and does not hinder the appearance of the fountain facility without the use of fractions.

1 is an exploded perspective view of a fountain nozzle assembly according to the present invention,
Figures 2 and 3 are cross-sectional views of the operation of the fountain nozzle assembly of Figure 1;

1 to 3, a fountain nozzle assembly 1 according to the present invention includes a fountain nozzle 10 for discharging water, a tube 20 for transferring water delivered from the outside to the fountain nozzle 10 And an optical fiber illumination means 30 for emitting illumination light to the inside and outside of the fountain nozzle 10 according to the presence or absence of supply of water to be delivered from the tube 20 to the fountain nozzle 10.

The fountain nozzle 10 has a fountain discharging space 11 formed therein and a nozzle hole 13 and a tubular body 13 are formed at the bottom of the fountain discharging space 11 corresponding to the inside of the rear end region of the fountain nozzle 10 And an optical fiber passage hole 15 through which an optical fiber 37 extending from the optical fiber passage 20 passes is formed.

An optical fiber entrance guider 17 for guiding the entrance and exit of the optical fiber 37 to be described later into and out of the fountain discharge space 11 is provided at the front end region of the fountain nozzle 10, Respectively.

A discharge port 18 is formed in the central portion of the optical fiber entrance guider 17 so as to discharge water to the outside and an optical fiber guide hole 19 (corresponding to the number of strands of the optical fiber 37) Is formed.

Here, it is preferable that the optical fiber 37 is provided in a plurality of strands and the optical fiber guide hole 19 is formed in a plurality corresponding to the number of the optical fibers 37. Of course, the optical fiber 37 may be formed as a single strand, and the optical fiber guide hole 19 may be formed as a single optical fiber guide hole 19 as occasion demands.

The distal end of the optical fiber 37 is positioned inside the optical fiber guide hole 19 and is drawn out through the optical fiber guide hole 19 in the process of supplying the water to the tube 20.

The tubular body 20 is a hollow body through which both sides in the longitudinal direction are penetrated. One longitudinal side thereof is engaged with the rear end of the fractional nozzle 10, and the other side is airtightly sealed by the airtight cap 21. The tubular body 20 and the fountain nozzle 10 may be coupled to each other directly using a female screw and a male thread structure or may be coupled to each other using a nipple 23 as shown in the drawing.

An optical fiber insertion hole 21a is formed in the airtight cap 21 coupled to the other longitudinal side of the tubular body 20 so that an optical fiber 37 extending from the outside is hermetically inserted into the tubular body 20. [ The optical fiber insertion hole 21a and the optical fiber 37 are hermetically sealed using a sealing member 21b. It goes without saying that the structure in which the optical fiber 37 is inserted into the tubular body 20 from the outside may be provided in the rear end region of the tubular body 20,

In addition, a water inlet hole 25 through which water supplied from the outside flows into the tubular body 20 is formed in a peripheral area of the tubular body 20 adjacent to the airtight cap 21. The water inflow hole 25 is hermetically connected to a water supply pipe 26 extending from an external water supply source. Needless to say, the water inflow hole 25 may be formed in the airtight cap 21 instead of the tubular body 20.

One end of the tubular body 20 to which the fractional nozzle 10 is coupled may be provided with a connection cap 27 for connecting the fractional nozzle 10 or the nipple 23 while sealing the tubular body 20 .

The optical fiber illumination means 30 includes a guide plunger 31 accommodated in the tube 20 and reciprocating in the longitudinal direction of the tube 20 depending on whether water is supplied or not, An optical fiber 37 having an end portion that goes into and out of the fountain discharge space 11 of the fountain nozzle 10 and a light source 39 that transmits light through the optical fiber 37.

The guide plunger 31 has a diameter smaller than the inner diameter of the tubular body 20 and is formed with an optical fiber fixing hole 33 to which the optical fiber 37 is fixed at the center. And a water passage hole 35 through which water passes.

The guide plunger 31 is moved toward the fountain nozzle 10 from inside the tubular body 20 by the water pressure of the water supplied to the tubular body 20 while the guide plunger 31 is moved toward the fountain nozzle 10 Lt; RTI ID = 0.0 > a < / RTI > Here, the positions of the optical fiber fixing hole 33 and the water passage hole 35 may vary depending on circumstances.

The optical fiber 37 is guided from the outside through the optical fiber insertion hole 21a of the airtight cap 21 to the inside of the tubular body 20 and through the optical fiber passage hole 15 of the fountain nozzle 10 toward the fractional discharge space 11 . The distal end region of the optical fiber 37 extended to the fountain discharging space 11 goes into and out of the fountain discharging space 11 of the fountain nozzle 10 through the optical fiber guide hole 19 of the optical fiber entrance guider 17 .

At this time, one longitudinal region of the optical fiber 37 located inside the tubular body 20 is fixed to the optical fiber fixing hole 33 of the guide plunger 31. As a result, when the guide plunger 31 reciprocates in the tubular body 20 in the presence or absence of the water supply, the distal end of the optical fiber 37 enters and exits the inside and the outside of the fountain discharge space 11.

The length of the optical fiber 37 located inside the tubular body 20 in the lower region of the guide plunger 31 has a length corresponding to the length of the reciprocating motion of the guide plunger 31, The end portion of the optical fiber 37 positioned in the fraction discharge space 11 of the fraction nozzle 10 can smoothly flow into and out of the fraction nozzle 10 according to the reciprocating movement.

As described above, the optical fibers 37 may be provided in a plurality of strands, and in some cases, they may be provided in a single strand.

The light source 39 may be provided as an LED that transmits light to the extended end of the optical fiber 37 extending to the outside of the tube 20. Light emitted from the light source 39 is transmitted to the entire length of the optical fiber 37.

Here, the light source 39 may be provided with a number of LEDs corresponding to the number of strands of the optical fibers 37, or may be provided with a single LED, and may transmit light to all the optical fibers 37 regardless of the number of strands of the optical fibers 37. Alternatively, the light source 39 may be a light emitting diode (LED) that emits light of different colors while being provided with LEDs corresponding to the number of strands of the optical fiber 37.

Of course, the light source 39 may be provided with various lamps such as a halogen lamp capable of emitting light in addition to the LED.

The light source 39 is electrically connected to the control unit 40 and the power supply unit 50 of the fountain system including the fountain nozzle assembly 1 according to the present invention and is connected to the light source 39 under the control of the control unit 40. [ The light source 39 may be turned on or off by allowing or blocking the supply of power to the light source.

Here, the control unit 40 may control the driving of the pumping unit (not shown) and the power supply unit 50, which pump the water from the external water supply source, to correspond to the preset driving program.

Here, the driving program may control the driving period and the driving time of the pumping unit (not shown) and the power supply unit 50. The driving program may include a pumping unit (not shown) (Not shown) and the power supply unit 50 can be controlled. When the light source 39 is provided with a plurality of LEDs, the control unit 40 controls the power supply unit 50 such that the LEDs can be controlled in various forms such as flashing the LEDs sequentially or collectively or irregularly, Can be controlled.

The operation of the fountain nozzle assembly 1 according to the present invention having such a configuration will now be briefly described.

2, the guide plunger 31 is spaced apart from the fountain nozzle 10 inside the tubular body 20, if no water is supplied from the external water supply source to the tubular body 20. In this state, the distal end of the optical fiber 37 is located inside the fractional discharge space 11 of the fractional nozzle 10 and is not exposed to the outside. At this time, the distal end of the optical fiber 37 is inserted into the optical fiber guide hole 19 of the optical fiber entrance guider 17 as described above.

3, when the water pumped from the external water supply source is transmitted to the inside of the tubular body 20 through the water supply pipe 26, the guide plunger 31 is guided by the water pressure of the water inside the tubular body 20, And moves to a position adjacent to the nozzle 10.

The distal end region of the optical fiber 37 is exposed to the outside of the fractional nozzle 10 by a predetermined length while the guide plunger 31 pushes the optical fiber 37 outwardly from the fractional discharge space 11 of the fractional nozzle 10 .

At this time, the control unit 40 of the fountain facility supplies power to the light source 39 so that the light source 39 emits light. When the light source 39 emits light, the light is transmitted to the distal end region of the optical fiber 37 exposed to the outside of the fountain nozzle 10 and is expressed to the outside.

The water supplied to the tubular body 20 passes through the water passage hole 35 of the guide plunger 31 and is strongly discharged to the outside through the nozzle hole 13 of the fountain nozzle 10. The water discharged to the outside improves the aesthetic effect of the fountain along with the illumination light emitted from the optical fiber 37.

Particularly, the distal end region of the optical fiber 37 exposed to the outside of the fountain nozzle 10 is moved arbitrarily while being in contact with the water discharged from the fountain nozzle 10 to divert the illumination light in various directions, thereby providing various points of the fountain Maximize aesthetic effects.

2, the guide plunger 31 is moved to a position spaced apart from the fountain nozzle 10 within the tubular body 20 by its own weight, as shown in Fig. 2, if the water is not supplied from the external water supply source do. At this time, the optical fiber 37 having one fixed area fixed to the optical fiber fixing hole 33 of the guide plunger 31 is pulled and the distal end region of the optical fiber 37 exposed to the outside of the fountain nozzle 10 passes through the fountain nozzle 10, And is introduced into the optical fiber guide hole 19 located inside the fractional discharge space 11 of the optical fiber guide hole 19. Thereby, when the water is not discharged to the fraction nozzle 10, the optical fiber 37 is not confirmed from the outside. Accordingly, when the fractional use is stopped, the optical fiber 37 does not hinder the appearance of the fountain facility.

As described above, according to the present invention, there is provided a fountain nozzle assembly capable of maximizing aesthetic effects by providing differentiated sights and aesthetics.

A fountain nozzle assembly is also provided that includes a lighting function and does not hinder the appearance of the fountain facility without the use of fractions.

10: Fountain nozzle 17: Optical fiber entrance guider
19: Fiber guide ball 20: Tubular body
30: optical fiber illumination means 31: guide plunger
37: Optical fiber

Claims (8)

delete In a fountain nozzle assembly,
A fountain nozzle having a fractional discharge space;
A tubular body coupled to the fractional nozzle at one side in the lengthwise direction and transferring water supplied from the outside to the fractional discharge space of the fractional nozzle;
A guide plunger accommodated in the tube and reciprocatingly moved toward and away from the fractional nozzle according to the supply of the water;
An optical fiber extending to the fractional discharge space through the tubular body and having one longitudinal direction region fixed to the guide plunger so that a distal end portion of the optical fiber enters and exits the inside and the outside of the fractional discharge space according to reciprocal movement of the guide plunger; And
And a light source that transmits light to the optical fiber,
Wherein an inlet of the fractional discharge space is provided with an optical fiber entrance guider for guiding the entrance and exit of the optical fiber. 3. The method of claim 2,
Wherein the optical fiber entrance guider has a discharge port formed at a central portion thereof and an optical fiber guide hole through which the optical fiber passes is formed in a peripheral region. The method of claim 3,
Wherein the optical fiber is provided in a plurality of strands, and the optical fiber guide hole is formed in a number corresponding to the number of strands of the optical fiber. In a fountain nozzle assembly,
A fountain nozzle having a fractional discharge space;
A tubular body coupled to the fractional nozzle at one side in the lengthwise direction and transferring water supplied from the outside to the fractional discharge space of the fractional nozzle;
A guide plunger accommodated in the tube and reciprocatingly moved toward and away from the fractional nozzle according to the supply of the water;
An optical fiber extending to the fractional discharge space through the tubular body and having one longitudinal direction region fixed to the guide plunger so that a distal end portion of the optical fiber enters and exits the inside and the outside of the fractional discharge space according to reciprocal movement of the guide plunger; And
And a light source that transmits light to the optical fiber,
Wherein a nozzle hole through which the water is discharged and an optical fiber through hole through which the optical fiber passes are formed in the bottom of the fraction discharge space. In a fountain nozzle assembly,
A fountain nozzle having a fractional discharge space;
A tubular body coupled to the fractional nozzle at one side in the lengthwise direction and transferring water supplied from the outside to the fractional discharge space of the fractional nozzle;
A guide plunger accommodated in the tube and reciprocatingly moved toward and away from the fractional nozzle according to the supply of the water;
An optical fiber extending to the fractional discharge space through the tubular body and having one longitudinal direction region fixed to the guide plunger so that a distal end portion of the optical fiber enters and exits the inside and the outside of the fractional discharge space according to reciprocal movement of the guide plunger; And
And a light source that transmits light to the optical fiber,
Wherein the guide plunger has an optical fiber fixing hole to which the optical fiber is fixed and a water passage hole through which the water passes. In a fountain nozzle assembly,
A fountain nozzle having a fractional discharge space;
A tubular body coupled to the fractional nozzle at one side in the lengthwise direction and transferring water supplied from the outside to the fractional discharge space of the fractional nozzle;
A guide plunger accommodated in the tube and reciprocatingly moved toward and away from the fractional nozzle according to the supply of the water;
An optical fiber extending to the fractional discharge space through the tubular body and having one longitudinal direction region fixed to the guide plunger so that a distal end portion of the optical fiber enters and exits the inside and the outside of the fractional discharge space according to reciprocal movement of the guide plunger; And
And a light source that transmits light to the optical fiber,
An airtight cap is coupled to the other longitudinal side of the tubular body, and the optical fiber extends outwardly through the airtight cap;
And a water inflow hole through which the water is supplied from the outside is formed in a peripheral region of the tube adjacent to the airtight cap. 8. The method of claim 7,
Wherein the light source is an LED that transmits light to an extreme end of the outwardly extending optical fiber.

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