KR102648578B1 - inclined water jet safety nozzle assembly for floor fountain - Google Patents

Abstract

An inclined angle spraying safety nozzle assembly for a floor fountain is disclosed. This safety nozzle assembly includes a guide tube extending in a vertical direction; a nozzle that rises along the guide pipe due to the hydraulic pressure of water flowing through the guide pipe and is formed by vertically combining a lower nozzle body and an upper nozzle body; A base coupled to the upper outer peripheral surface of the guide tube; a nozzle cap coupled to the base and having a nozzle exposure hole; A shutter that is pushed by a rising nozzle and changes from a closed state blocking the upper side of the nozzle to an open state opening the upper side of the nozzle; and a shutter lock that locks the shutter in a closed state when the nozzle is lowered, wherein the lower nozzle body includes a lower nozzle hole communicating with the inside of the guide tube, and the upper nozzle body includes the lower nozzle hole. It is connected to and includes an upper nozzle hole having a predetermined inclination angle, and the central axis of the lower nozzle hole and the central axis of the upper nozzle hole intersect at a predetermined angle.

Description

Inclined water jet safety nozzle assembly for floor fountain}

The present invention relates to a safety nozzle assembly for a floor fountain, and more specifically, to a safety nozzle assembly for a floor fountain with an inclined angle spray function.

Compared to typical fountains that people can only see with their eyes from a distance, floor fountains are different in that they are installed so that people can easily access the area where the water spews out. However, existing floor fountains have always had a risk of safety accidents due to the characteristic of allowing people to access the installation location. In other words, in existing floor fountains, the nozzle and the inside of the nozzle pipe are always exposed to the outside regardless of the time of water injection, so the human body (especially the feet or hands) of people (especially young high) who approach the installation area are exposed to the outside. There was a high risk of safety accidents such as getting caught in the nozzle installation hole or the holes around the nozzle. In addition, in conventional floor fountains, foreign substances accumulate inside the nozzle exposed to the outside, causing the nozzle to not function properly. Additionally, existing nozzles have a high risk of being damaged by people.

Accordingly, there is a need for a floor fountain in which the opening of the cover covering the nozzle is closed in normal times and the opening is opened only when the fountain is used. In response to this, devices configured to open the nozzle opening in conjunction with the nozzle's rise have been proposed. However, this device has the disadvantage that the structure for opening and closing the opening in response to the elevation of the nozzle is complex and requires many parts. In particular, the above device has a structure that opens the opening by lifting the opening and closing door that covers the nozzle while the upper end of the nozzle is spaced apart from the nozzle as the nozzle rises. This reduces the reliability of opening and can be located around the opening and closing door. There was a risk of failure due to existing variables (e.g., accumulation of foreign matter), and the nozzle had to protrude above the floor, so there was a high risk of damage to the nozzle and its surrounding parts.

Meanwhile, the nozzle assembly for a fountain includes a nozzle in which a nozzle hole is formed. However, the conventional fountain nozzle assembly has a structure in which water is sprayed through a single nozzle hole extending vertically from the bottom of the nozzle to the top of the nozzle, so it was difficult to implement fountain water at various angles. If the nozzle hole is formed to be apart at a certain angle with respect to the vertical center axis of the nozzle, inclined angle spraying is possible. However, since the angle of the nozzle hole is limited by the distance from the top to the bottom of the nozzle, that is, the total vertical length of the nozzle, the desired It is impossible to form nozzle holes at various intended angles.

Korean Patent Registration No. 10-1728880 (April 14, 2017) Korean Patent Registration No. 10-0998629 (November 30, 2010) Korean Utility Model Registration No. 20-0450165 (September 2, 2010) Korean Patent Registration No. 10-0916247 (September 1, 2009) Korean Patent Registration No. 10-1010903 (January 19, 2011) Korean Registered Patent No. 10-2165251 (October 6, 2020)

The problem to be solved by the present invention is to consist of a nozzle with a lower nozzle body formed with a lower nozzle hole and an upper nozzle body formed with an upper nozzle hole connected to the lower nozzle hole, and the upper nozzle hole is formed with respect to the vertical length of the upper nozzle body. The object is to provide an inclined angle spray safety nozzle assembly for a floor fountain that can implement a nozzle with a more diverse or expanded spray angle by forming it at an inclined angle.

An inclined angle spraying safety nozzle assembly for a floor fountain according to one aspect of the present invention includes a guide pipe extending in a vertical direction; a nozzle that rises along the guide pipe due to the hydraulic pressure of water flowing through the guide pipe and is formed by vertically combining a lower nozzle body and an upper nozzle body; A base coupled to the upper outer peripheral surface of the guide tube; a nozzle cap coupled to the base and having a nozzle exposure hole; A shutter that is pushed by a rising nozzle and changes from a closed state blocking the upper side of the nozzle to an open state opening the upper side of the nozzle; and a shutter lock that locks the shutter in a closed state when the nozzle is lowered, wherein the lower nozzle body includes a lower nozzle hole communicating with the inside of the guide tube, and the upper nozzle body includes the lower nozzle hole. It is connected to and includes an upper nozzle hole having a predetermined inclination angle, and the central axis of the lower nozzle hole and the central axis of the upper nozzle hole intersect at a predetermined angle.

An inclined angle spraying safety nozzle assembly for a floor fountain according to another aspect of the present invention includes a guide pipe extending in a vertical direction; a nozzle that rises along the guide pipe due to the hydraulic pressure of water flowing through the guide pipe and is formed by vertically combining a lower nozzle body and an upper nozzle body; A base coupled to the upper outer peripheral surface of the guide tube; a nozzle cap coupled to the base and having a nozzle exposure hole; A shutter that is pushed by a rising nozzle and changes from a closed state blocking the upper side of the nozzle to an open state opening the upper side of the nozzle; and a shutter lock that locks the shutter in a closed state when the nozzle is lowered, wherein the lower nozzle body includes a lower nozzle hole communicating with the inside of the guide tube, and the upper nozzle body includes the lower nozzle hole. and a plurality of upper nozzle holes commonly connected to each other, and at least one of the plurality of upper nozzle holes may be an inclined nozzle hole that obliquely intersects the central axis of the lower nozzle hole.

A guide pin is installed on the inner peripheral surface of the guide pipe to protrude inward, and a long guide groove is formed in the vertical direction on the outer peripheral surface of the lower nozzle body corresponding to the guide pin, through cooperation between the guide pin and the guide groove. , the nozzle moves up and down without rotation, the upper end of the lower nozzle hole is located deviated to one side from the center of the nozzle, and the upper end of the upper nozzle hole is located deviated in a direction opposite to the direction in which the upper end of the lower nozzle hole is deviated, The upper nozzle body includes an upper tapered portion that gradually converges toward the apex of the upper end, and the shutter includes a pair of hinge brackets installed to face each other across an opening formed in the center of the base, and the pair of hinge brackets. It includes a pair of shutter blades hinged so as to be opened or gathered together with respect to each other by a hinge axis installed on A weight is formed at each lower end of the blades, which lowers under its own weight to keep the pair of shutter blades in a closed state while the nozzle descends and does not interact with the shutter, and is formed at an upper end of the pair of blades. In the closed state, shutter plates are formed close to each other to block the upper side of the nozzle, locking grooves are formed on each of the pair of shutter blades, and the shutter lock includes a lock piece rotatably installed on a pivot axis, and It includes a spring that biases the locking piece in a direction in which it is inserted into the locking groove when the nozzle is lowered.

According to the present invention, the nozzle is composed of a lower nozzle body formed with a lower nozzle hole and an upper nozzle body formed with an upper nozzle hole connected to the lower nozzle hole, and the upper nozzle hole is inclined at an angle with respect to the vertical length of the upper nozzle body. By forming, it is possible to implement a nozzle having a more diverse or expanded range of spray angles.

1 is a view showing a floor fountain in which an inclined angle spray nozzle assembly for a fountain is installed according to an embodiment of the present invention;
Figure 2 is a perspective view showing an inclined angle spray nozzle assembly for a fountain according to an embodiment of the present invention;
Figure 3 is an exploded perspective view showing an inclined angle spray nozzle assembly for a fountain according to an embodiment of the present invention;
Figure 4 is a cross-sectional view showing the inclined angle spray nozzle assembly for a fountain in a closed state according to an embodiment of the present invention;
Figure 5 is a cross-sectional view showing the inclined angle spray nozzle assembly for a fountain in an open state according to an embodiment of the present invention, and Figure 6 is a cross-sectional view taken along AA of Figure 5,
Figures 7 (A) to (L) exemplarily show inclined angle spray nozzle assemblies for various fountains that can be applied to one fountain system to implement fountain water streams at various angles,
Figure 8 shows exemplary fountain water shapes that can be realized when using the above-described inclined angle fountain nozzle assembly,
9 and 10 are views for explaining a spray nozzle assembly according to another embodiment of the present invention.

Hereinafter, with reference to the attached drawings, embodiments of the present invention will be described in detail so that those skilled in the art can easily practice the present invention. The invention may be implemented in many different forms and is not limited to the embodiments described herein.

In explaining the present invention, the size or shape of components shown in the drawings may be exaggerated or simplified for clarity and convenience of explanation.

Additionally, terms specifically defined in consideration of the configuration and operation of the present invention may vary depending on the intention or custom of the user or operator. These terms should be interpreted as meanings and concepts consistent with the technical idea of the present invention based on the content throughout this specification.

In order to clearly explain the present invention, descriptions of parts unrelated to the technical idea of the present invention have been omitted, and identical or similar components are assigned the same reference numerals throughout the specification.

Additionally, in various embodiments, components having the same configuration will be described using the same symbols only in the representative embodiment, and in other embodiments, only components that are different from the representative embodiment will be described.

Throughout the specification, when a part is said to be “connected” to another part, this includes not only “directly connected” but also “indirectly connected” through another member. Additionally, when a part "includes" a certain component, this may mean that it further includes other components rather than excluding other components, unless specifically stated to the contrary.

Figure 1 is a view showing a floor fountain in which an inclined angle spray nozzle assembly for a fountain is installed according to an embodiment of the present invention, and Figure 2 is a perspective view showing an inclined angle spray nozzle assembly for a fountain according to an embodiment of the present invention. 3 is an exploded perspective view showing the inclined angle spray nozzle assembly for a fountain according to an embodiment of the present invention, and Figure 4 is a cross-sectional view showing the inclined angle spray nozzle assembly for a fountain according to an embodiment of the present invention in a closed state. 5 is a cross-sectional view showing the inclined angle spray nozzle assembly for a fountain in an open state according to an embodiment of the present invention, and FIG. 6 is a cross-sectional view taken along A-A of FIG. 5.

Referring to Figure 1, the inclined angle spray nozzle assembly 1 for the fountain can be seen as part of the floor fountain installed on the flooring material A. At this time, the top surface of the inclined angle spray nozzle assembly 1 for the fountain, more specifically, the top surface of the nozzle cap 900 described below, is substantially on the same plane as the top surface of the flooring material A. It is desirable to have

2 to 6, the inclined angle spray nozzle assembly 1 for a fountain rises along the guide pipe 300 by the guide pipe 300 and the water pressure of the water flowing through the guide pipe 100, and has a lower portion. A nozzle 100 formed by combining the nozzle body 120 and the upper nozzle body 140, a base 200 coupled to the upper outer peripheral surface of the guide tube 300, and a nozzle exposed. A cylindrical nozzle cap 900 with a hole 910 formed at the top. The shutter 400 is pushed by the rising nozzle 100 and changes from a closed state blocking the upper side of the nozzle 100 to an open state opening the upper side of the nozzle 100, and a state in which the nozzle 100 is lowered. includes a shutter lock 500 that locks the shutter 400 in a closed state. The shutter 400 includes a pair of shutter blades 420, 420 that are hinged, and in the closed state, the pair of shutter blades 420, 420, which are closed to each other, are opened by the rising nozzle 100. It changes to the open state.

The guide pipe 300 is provided at the end of the fountain pipe (not shown) and extends vertically, and allows the fountain water stream to flow toward the nozzle 100 slidably installed on its inner upper side. At the same time, it serves to guide the nozzle 100, which rises due to water pressure, to a certain height. A step 320 is formed on the inner peripheral surface of the guide tube 300 to limit the nozzle 100 from descending below a certain height.

Meanwhile, the nozzle 100 is configured to spray a stream of water at a predetermined inclination angle, so if the nozzle 100 rotates while rising, the fountain water stream will not be sprayed in the intended direction. In order to prevent this, the nozzle 100 and the guide pipe 300 suppress the rotation of the nozzle 100 while the nozzle 100 rises or falls along the guide pipe 300. ) A guide means is provided to guide the linear motion of ). In this embodiment, the guide means includes a guide pin 340 installed to protrude inward on the inner peripheral surface of the guide pipe 300 and a vertical direction on the outer peripheral surface of the lower nozzle body 120 corresponding to the guide pin 340. It includes a long guide groove 122. A guide pin 340 is inserted into the guide groove 122, and when the nozzle 100 rises, the guide pin 340 moves along the guide groove 122, and the nozzle 100 moves up and down without rotation. Guides you to move to . The top of the guide groove 122 is blocked by the bottom of the upper nozzle body 140, which prevents the nozzle 100 from rising above a certain height.

As mentioned above, the nozzle 100 is formed by combining the lower nozzle body 120 and the upper nozzle body 140. The lower nozzle body 120 includes a lower nozzle hole 124 that communicates with the inside of the guide tube 300, and the upper nozzle body 140 is connected to the lower nozzle hole 124 and has an upper nozzle having a certain inclination angle. Includes hole 144. At this time, the central axis of the lower nozzle hole 124 and the central axis of the upper nozzle hole 144 intersect at an obtuse angle.

If the nozzle is not composed of a combined structure of a lower nozzle body and an upper nozzle body with nozzle holes crossing each other, but includes a single nozzle hole formed at a certain inclination angle from the bottom to the top, the inclination angle of the nozzle hole is proportional to the length of the nozzle. is limited by, and therefore, the spray inclination angle of the fountain water stream will also be limited by it. Although it has been considered to form a nozzle hole with two slopes in a nozzle made of a single nozzle body, this has the limitation that machining of the nozzle hole is practically impossible.

Meanwhile, in this embodiment, the spray inclination angle of the fountain water stream is limited by the length of the upper nozzle body 140, so it is possible to spray at a larger inclination angle.

At this time, it is preferable that the upper end of the lower nozzle hole 124 is offset to one side by a certain distance from the center C of the nozzle 100, and the upper nozzle hole 144 is connected to the upper end of the lower nozzle hole 124. It extends obliquely away from the top of the lower nozzle hole 124 not only in the height direction but also in the lateral direction. It is preferable that the upper end of the lower nozzle hole 124 and the upper end of the upper nozzle hole 144 are spaced apart from each other as far as possible with respect to the center of the nozzle 100.

In addition, the lower nozzle body 120 includes a reservoir 123 formed at a certain height from the bottom, and the lower nozzle hole 124 has a smaller cross-sectional size than the reservoir 123. ) and extends vertically to the top of the lower nozzle body 120. The reservoir 123 is formed to primarily collect water that has passed through the guide pipe 300, and serves to increase the force pushing up the nozzle 100. The lower nozzle hole 124 has a vertically extending shape and is connected to the upper end of the reservoir 123 while being biased to one side from the center of the nozzle 100. Accordingly, the lower nozzle hole 124 ) is eccentric to one side from the center of the nozzle 100.

The lower nozzle body 120 has a coupling protrusion 125 at its upper end, and the upper nozzle body 140 has a coupling groove 145 into which the coupling protrusion 125 is inserted at its lower end. In a state where the coupling protrusion 125 is inserted into the coupling groove 145, a fixing pin 149 laterally penetrating the sleeve 146 defining the coupling groove 145 is formed on the coupling protrusion 125. By fastening to the pinhole, the upper nozzle body 140 and the lower nozzle body 120 are coupled to each other. At this time, the upper end of the lower nozzle hole 124 is located in the coupling protrusion 125 and the lower end of the upper nozzle hole 144 is located in the coupling groove 145.

In addition, the upper nozzle body 140 includes an upper tapered portion 147 that gradually converges toward the apex of the upper end, and this upper tapered portion 147 allows the rising nozzle 100 to perform a shutter lock (described below). Unlocking the shutter 400 and opening the shutter 400 by sequentially rotating and opening the pair of locking pieces 520 and 520 constituting the shutter 400 and the pair of shutter blades 420 and 420 constituting the shutter 400. ) It also helps to perform the opening of ) more smoothly.

The above-described shutter 400 is installed on an annular base 200 that is screwed to the upper end of the guide tube 300. More specifically, the shutter 400 includes a pair of hinge brackets 402 installed to face each other across an opening 201 formed in the center of the base 200, and a pair of hinge brackets 402 installed on the hinge brackets 402. It includes a pair of shutter blades 420 and 420 that are hinged to be opened or brought together with respect to each other by a hinge axis 410. Each of the pair of shutter blades 420 includes a pair of lower blades and a pair of upper blades, and an end of each pair of lower blades is in a closed state, that is, the nozzle 100 is lowered to lower the shutter. A weight 430 is formed that lowers under its own weight while not acting on the 400 to allow the pair of shutter blades 400 to be in a closed state, and the upper ends of the pair of blades are close to each other in the closed state. Thus, a shutter plate 440 can be formed that blocks the upper side of the nozzle 100, more specifically, the nozzle exposure hole 910.

At this time, the upper wing and the lower wing are connected at an angle of approximately 90 degrees, and the hinge shaft 410 described above is installed at the area where the lower wing and the upper wing are connected. Additionally, a locking groove 422 is formed in each of the pair of shutter blades 420. In addition, the above-described shutter lock 500 includes a pair of hinge brackets 402 and a pair of rotation axes 510 installed in parallel. A pair of locking pieces (520, 520) rotatably installed on the pair of rotation shafts (510), and a pair of locking pieces (520, 520) formed at the upper end of the hinge bracket (402) and the locking pieces (520, 520) are attached to the hinge bracket ( 520, 520, a pair of cut grooves 502, 502 that allow rotation inward, and installed on the rotation axis 510, in a state in which the nozzle 100 is lowered, the locking piece 520, It includes a spring 530 that biases 520) in the direction in which it is inserted into the locking groove 422. The nozzle 100, which rises due to water pressure, rotates the locking pieces 520 and 520 while opposing the biasing force of the spring 530, causing the locking pieces 520 and 520 to fall out of the locking groove 422. Release locking. In the unlocked state, when the nozzle 100 rises further, the shutter 400 is opened by spreading a pair of shutter blades 420, 420.

As described above, the nozzle 100 is composed of a lower nozzle body 120 with a lower nozzle hole 124 and an upper nozzle body 140 with an upper nozzle hole 144, and not the entire nozzle. Since the spray inclination angle of the fountain water stream can be determined by the inclination angle of the upper nozzle hole 144 formed in (140), the spray inclination angle can be determined within a larger angle range.

7 (A) to (L) exemplarily show various inclination angle spray nozzle assemblies that can be applied to one fountain system to implement fountain water streams of various angles. Referring to this, the angle of the upper nozzle hole, the upper nozzle It is possible to apply spray nozzle assemblies that can spray fountain water streams at various inclination angles depending on the starting position of the hole, the width of the upper nozzle hole, etc. If necessary, an inclined angle spray nozzle assembly in which a nozzle hole of one inclined angle is formed in a single nozzle, and an inclined angle spray nozzle assembly in which the upper inclined hole and the lower inclined hole have different inclinations, as in this embodiment, may be used together in one fountain system. there is.

Figure 8 exemplarily shows fountain water shapes that can be implemented when using the above-described inclined angle fountain nozzle assembly.

9 and 10 are views for explaining a spray nozzle assembly according to another embodiment of the present invention.

Referring to FIGS. 9 and 10, the inclined angle spray nozzle assembly 1' according to the present embodiment has a guide pipe 300 and is sprayed along the guide pipe 300 by the hydraulic pressure of water flowing through the guide pipe 300. A nozzle 100' rising and formed by combining a lower nozzle body 120' and an upper nozzle body 140', a base 200 coupled to the upper outer peripheral surface of the guide tube 300, and the base ( 200) and a cylindrical nozzle cap 900 with a nozzle exposure hole 910 formed at the top. A shutter 400 that is pushed by the rising nozzle 100' and changes from a closed state blocking the upper side of the nozzle 100' to an open state opening the upper side of the nozzle 100, and the nozzle 100' It includes a shutter lock 500 that locks the shutter 400 in a closed state in the lowered state. The shutter 400 includes a pair of shutter blades 420, 420 that are hinged, and in the closed state, the pair of shutter blades 420, 420, which are closed to each other, are raised by a nozzle 100'. It spreads out and changes into an open state.

The guide pipe 300 is provided at the end of the fountain pipe (not shown) and extends in the vertical direction, allowing the flow of the fountain water stream toward the nozzle 100' and at the same time rising by water pressure. It serves to guide the nozzle (100') to a certain height.

As in the previous embodiment, the nozzle 100' and the guide tube 300 are provided with a guide means that guides the nozzle 100' while suppressing its rotation while the nozzle 100' moves up and down.

The nozzle 100' is formed by combining a lower nozzle body 120' and an upper nozzle body 140'. The lower nozzle body 120' includes one lower nozzle hole 124' communicating with the inside of the guide tube 300, and the upper nozzle body 140' is common with the lower nozzle hole 124'. It includes a plurality of upper nozzle holes (142', 144') connected to each other. In this embodiment, the upper nozzle holes 142' and 144' are connected to the lower nozzle hole 124' at the bottom and have one vertical lower nozzle hole coincident with the center of the lower nozzle hole 124'. (142') and a plurality of inclined lower nozzle holes (144') that are commonly connected to the lower nozzle hole (124') at the bottom and intersect to form an obtuse angle with the center of the lower nozzle hole (124'). You can.

Since one nozzle 100' is used in which a plurality of upper nozzle holes 142' and 144' are commonly connected to one lower nozzle hole 122', only that one nozzle 100' is used. Using this, you can form multiple fountains.

The remaining configuration is substantially the same as the previous embodiment, and therefore, further description is omitted to avoid duplication.

Note that the present invention can be implemented with various modifications without being limited by the above-described embodiments.

100: nozzle 120, 120': lower nozzle body
124, 124': Lower nozzle hole 140, 140': Upper nozzle body
144, 142', 144': upper nozzle hole 200: base
300: Guide tube 400: Shutter
500: Shutter lock 900: Nozzle cap

Claims (3)

A guide tube extending vertically;
a nozzle that rises along the guide pipe due to the hydraulic pressure of water flowing through the guide pipe and is formed by vertically combining a lower nozzle body and an upper nozzle body;
A base coupled to the upper outer peripheral surface of the guide tube;
a nozzle cap coupled to the base and having a nozzle exposure hole;
A shutter that is pushed by a rising nozzle and changes from a closed state blocking the upper side of the nozzle to an open state opening the upper side of the nozzle; and
It includes a shutter lock that locks the shutter in a closed state when the nozzle is lowered,
The lower nozzle body includes a lower nozzle hole that communicates with the inside of the guide pipe, and the upper nozzle body includes an upper nozzle hole connected to the lower nozzle hole and having a predetermined inclination angle, and the central axis of the lower nozzle hole and The central axis of the upper nozzle hole intersects at a certain angle,
A guide pin is installed on the inner peripheral surface of the guide pipe to protrude inward, and a long guide groove is formed in the vertical direction on the outer peripheral surface of the lower nozzle body corresponding to the guide pin, through cooperation between the guide pin and the guide groove. , the nozzle moves up and down without rotation, the upper end of the lower nozzle hole is located deviated to one side from the center of the nozzle, and the upper end of the upper nozzle hole is located deviated in a direction opposite to the direction in which the upper end of the lower nozzle hole is deviated, The upper nozzle body includes an upper tapered portion that gradually converges toward the apex of the upper end, and the shutter includes a pair of hinge brackets installed to face each other across an opening formed in the center of the base, and the pair of hinge brackets. It includes a pair of shutter blades hinged so as to be opened or gathered together with respect to each other by a hinge axis installed on A weight is formed at each lower end of the blades, which lowers under its own weight to keep the pair of shutter blades in a closed state while the nozzle descends and does not interact with the shutter, and is formed at an upper end of the pair of blades. In the closed state, shutter plates are formed close to each other to block the upper side of the nozzle, locking grooves are formed on each of the pair of shutter blades, and the shutter lock includes a lock piece rotatably installed on a pivot axis, and An inclined angle spraying safety nozzle assembly for a floor fountain, comprising a spring that biases the locking piece in a direction in which it is inserted into the locking groove when the nozzle is lowered. delete delete

Images