KR101190873B1 - The axis of rotation and ring structure having the same - Google Patents

Abstract

PURPOSE: A rotary shaft and ring structure including the same are provided to discharge water using a nozzle by rotating the ring structure. CONSTITUTION: A housing is located between a fixing side structure(100) and a rotation side structure(200). A fixing sleeve is fixed to the housing. A rotation sleeve is rotatably installed in the housing. The rotation sleeve is combined with the fixing sleeve. One ends of fixing sleeve and the rotation sleeve are opened. Other ends of the fixing sleeve and the rotation sleeve are projected to both sides of the housing.

Description

The axis of rotation and ring structure having the same}

The present invention relates to a ring structure having a rotating shaft and a rotating shaft, and more particularly, by installing a rotating shaft between the fixed ring structure and the rotating ring structure located in the fixed ring structure to eject water while rotating the rotating ring structure, providing a sense of liveliness and visuality. A ring structure having a rotating shaft and a rotating shaft that can enhance the effect.

In general, fountains are installed in lakes, ponds, and rivers in parks to purify water and purify the air, while at the same time spewing water to create dynamic beauty and coolness.

The fountain operates by pumping up the water stored in the lower tank and the reservoir tank, and ejecting the water through the nozzle.

In recent years, the emphasis on design elements, and fountains not only act as a fountain in the pure sense of the above, but also highlights the design effect by illuminating the water ejected by installing lights of various colors on or near the fountain.

As a fountain, a nozzle is installed on the bottom of the reservoir tank to spray water into the water, or a fountain or pond fountain.The nozzle is installed at the bottom of the bottom plate so that only the nozzle outlet is exposed on the bottom of the fountain. There are floor fountains, and there are various types of fountains, such as sculpture fountains, dead fountains, indoor fountains, transition fountains, and waterfall fountains.

On the other hand, in recent years, the intensity or direction of the water to be ejected by changing the sound and the like to give a rhythmic feeling to the water ejected from the fountain to improve the aesthetics, such as to obtain a variety of effects using the fountain.

In general, by moving the nozzle in various directions to increase the dynamic or visual effect, the fountain with dynamic movement than the fixed fountain can be more vibrant or visual effect.

It is an object of the present invention to provide a ring structure having a rotating shaft and a rotating shaft capable of increasing water and visual effects by ejecting water through the nozzle while the ring structure in which the nozzle is formed is rotated.

In addition, another object of the present invention is to provide a ring structure having a rotating shaft and a rotating shaft that can allow a plurality of ring structures to rotate in different directions to further enhance liveliness and visual effects.

The present invention for achieving the above object is located between the fixed side structure and the rotating side structure, the housing fixed to the fixed side structure or the rotating side structure; A fixed sleeve fixed to the housing; And a rotatable sleeve rotatably installed in the housing, the rotatable sleeve being coupled to the rotatable sleeve, wherein the rotatable sleeve and one end of the rotatable sleeve are open, coupled to each other in the rotatable sleeve, the rotatable sleeve and the rotatable sleeve. The other ends of the sleeves respectively protrude to both sides of the housing, one providing the axis of rotation located on the stationary side structure and the other on the rotating side structure.

The rotation shaft may include a driving motor installed at any one of the fixed side structure, the rotation side structure, and the housing to rotate the rotation sleeve.

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On the other hand, the fixed sleeve, one end of any one of the rotary sleeve includes a sealing groove for airtightness, and a sealing member seated in the sealing groove, the fixing sleeve protruding from the housing and the rotating sleeve At least one hole is formed at the other end, and pipes through which water moves are respectively coupled to the holes.

In this case, the fixing sleeve and the rotating sleeve are formed by concentrically arranging sub-sleeves having different diameters so that an inner space can be formed. One end of the fixing sleeve and the rotating sleeve are combined to form a sub-sleeve of the fixing sleeve. And sub-sleeves of the rotating sleeve respectively engage with each other.

The rotating shaft may include a slip ring that electrically connects the other end of any one of the fixed sleeve and the rotary sleeve or the fixed sleeve, and even if the rotary sleeve rotates inside any one of the rotary sleeve. Include.

The present invention is a fixed ring structure; A rotating ring structure installed in the fixed ring structure; A housing fixed between the fixed ring structure and the rotary ring structure, the housing fixed to the fixed ring structure or the rotary ring structure, and a fixed sleeve fixed to the housing; And a rotatable sleeve rotatably installed in the housing, the rotatable sleeve being coupled to the rotatable sleeve, wherein the rotatable sleeve and one end of the rotatable sleeve are open and coupled to each other in the housing, the rotatable sleeve and the rotatable sleeve The other end of each protrudes to both sides of the housing, one is provided in the fixed side structure, the other provides a ring structure having a rotation axis located in the rotating side structure.

In this case, the fixed ring structure, the rotary ring structure, installed in any one of the housing, and includes a drive motor for rotating the rotary sleeve.

On the other hand, the rotary ring structure is provided with two or more of different diameter, each of the rotary ring structure is smaller than the inner diameter of the large rotary ring structure is formed smaller outer diameter, the large rotary ring structure and the small rotary ring Between the structures includes at least one axis of rotation such that the small rotating ring structure can rotate within the large rotating ring structure.

The fixed ring structure is a truss structure is provided in a ring shape, the lower portion coupled to the support for supporting the fixed ring structure is formed in a wider view from the side, the upper portion is formed to be narrower to have a slope narrowing to the top The cross-sectional shape is provided with a thick width on the outer diameter side and a narrow width on the inner diameter side.

On the other hand, the rotary ring structure is installed directly adjacent to the fixed ring structure may have a spherical shape.

According to the present invention, the ring structure in which the nozzle is formed may rotate to eject water through the nozzle to increase the vividness and visual effect, and also allow the plurality of ring structures to rotate in different directions to bring the dynamic and visual effect. Can be further increased.

1 is a view schematically showing the configuration of a ring structure fountain according to an embodiment of the present invention.
2 is an enlarged view illustrating a ring structure according to an exemplary embodiment of the present invention of FIG. 1.
FIG. 3 is an enlarged view of region A of FIG. 2.
FIG. 4 is an enlarged view of region B of FIG. 2.
FIG. 5 is an enlarged view of region C of FIG. 2.
6 to 9 illustrate first to fourth water movement paths according to an exemplary embodiment of the present invention.
10 is a flowchart showing a ring structure fountain construction procedure according to an embodiment of the present invention.

DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENTS Reference will now be made in detail to the preferred embodiments of the present invention, examples of which are illustrated in the accompanying drawings, wherein like reference numerals refer to the like elements throughout. Here, the embodiments of the present invention are provided to sufficiently convey the technical spirit of the present invention to those skilled in the art, and the present invention is not limited to the embodiments described below, and may be embodied in other forms.

In addition, in the description of the present invention, terms defined are defined in consideration of functions in the present invention, and should not be interpreted to limit the technical components of the present invention. The terms '2' and 'third' are used to describe different components, and are used to distinguish one component from other components.

1 is a view schematically showing the configuration of a ring structure fountain according to an embodiment of the present invention, Figure 2 is an enlarged view showing a ring structure according to an embodiment of the present invention, Figure 3 is a region A of FIG. 4 is an enlarged view of region B of FIG. 2, FIG. 5 is an enlarged view of region C of FIG. 2, and FIGS. 6 to 9 are first to fourth views according to embodiments of the present disclosure. Figure 10 is a view showing the water movement path of, Figure 10 is a flow chart showing the construction sequence of the ring structure fountain according to an embodiment of the present invention.

1 and 2, a ring structure fountain according to an embodiment of the present invention includes a plurality of ring structures, and includes a fixed ring structure 100 and one or more rotating ring structures installed in the fixed ring structure 100. 200, a rotation shaft 300 for rotating the rotary ring structure 200. Therefore, the fixed ring structure 100 is installed on the outermost side, and has a ring shape.

However, in the present embodiment, the rotary shaft 300 is installed between the fixed ring structure 100 and the rotary ring structure 200 as an example, but the rotary shaft 300 is limited to being installed between the ring structure It is not positioned between the fixed side structure and the rotating side structure, it is provided to rotate the rotating side structure.

In this case, a support 10 for supporting the fixed ring structure 100 may be installed below the fixed ring structure 100. In addition, the rotating shaft 300 includes a pipe so as to serve as a pipe to move the water.

The upper end of the support 10 forms a protruding portion protruding upward to form an arc-shaped seating portion on which the fixed ring structure 100 may be seated, and the stationary ring structure 100 seated on the arc-shaped seating portion. A fitting groove is opened downwardly between the inner diameter frame and the outer diameter frame so that the fixing ring structure 100 is fixed to the support 10 by coupling the fitting groove to the protrusion.

Meanwhile, the rotating shaft 300 includes first to third rotating shafts 310 to 330, which will be described in detail later.

The fixed ring structure 100 is formed in a circular shape perpendicular to the front, and may be formed in a size of about 40m in diameter, but the shape and size of the fixed ring structure 100 is not limited thereto. Accordingly, the fixed ring structure 100 may have another shape such as an ellipse, and the size may be appropriately selected according to the installation space.

The fixed ring structure 100 and the rotating ring structure 200 is preferably formed of a material that can have a light and robust durability, and can be formed by bending the H-beam and I-beam with a certain curvature, the truss structure It may be configured by combining in the form of a ring, it may be implemented by mixing the beam and the truss structure.

In particular, the fixed ring structure 100 is provided in a truss structure in a ring shape, the lower portion is coupled to the support 10 is formed in a wide view from the side, the upper portion is formed in a narrow width, narrowed to the top It is provided to have an inclination, the cross-sectional shape is formed in the outer diameter side is thick, the inner diameter side is narrow.

In the present embodiment, the rotary ring structure 200 includes first to third rotary ring structures 210 to 230. That is, while three rotary ring structures are installed as an example, the number of installation of the rotary ring structure 200 can be appropriately selected by those skilled in the art according to the installation space and the need.

On the other hand, the first to third rotating ring structures 210 to 230 are sequentially installed, the first rotating ring structure 210 is installed in the fixed rotating ring structure 100, the first rotating ring The second rotating ring structure 220 is installed in the structure 210, and the third rotating ring structure 230 is installed in the second rotating ring structure 220.

At this time, any one ring structure is installed in the other ring structure is not installed inside the other ring structure, it means that is installed spaced apart from the other ring structure, is formed to have a smaller diameter.

Therefore, the rotary ring structure 200 is provided with two or more different in diameter, each of the rotary ring structure is smaller than the inner diameter of the rotary ring structure is smaller than the inner diameter of the large rotary ring structure, wherein at least one rotating shaft 300 is installed between the large rotating ring structure and the small rotating ring structure to rotate the small rotating ring structure within the large rotating ring structure.

In this case, the first and second rotating ring structures 210 and 220 may be ring-shaped, and the third rotating ring structure 230 installed at the innermost side may be formed in a spherical shape. Such a structure, that is, a structure in which the innermost rotating ring structure is formed in a spherical shape may be applied regardless of the number of rotating ring structures. Of course, the third rotating ring structure may be ring-shaped, not spherical.

In addition, a rotary ring structure which is not provided with a ring-shaped rotating ring structure after the fixed ring structure 100 is optionally installed, and is formed immediately adjacent to the fixed ring structure 100. May be in the form of a sphere.

On the other hand, the lighting unit 500 is installed in the third rotating ring structure 230 is formed in a sphere shape is installed on the innermost. In this case, the lighting unit 500 may be formed of a plurality of LEDs so as to emit light of various colors, the surface of the third rotating ring structure 230 may be formed of colored glass to increase the visual effect. .

In addition, the ring structure fountain includes a fountain device to perform the fountain function, which includes a plurality of pipes through which water moves.

In addition, the water fountain device is installed in the water tank 20 in which water for supplying the support 10 or the plurality of pipes is stored, and pumps water to supply the plurality of pipes 30 to the pipes. Include.

In addition, the fountain device is a nozzle for discharging the water pumped from the pump 30, a pipe for supplying water from the pump 30 to the nozzle, at least one valve installed in the pipe to control the flow of water, A lighting fixture installed on the nozzle to illuminate the water discharged through the nozzle, an electric control panel for controlling a power supply of the pump, the valve, the lighting fixture, and at least one connected from the electric control panel to the pump, the valve, the lighting fixture. And a control unit for applying power control and communication signals to the cable and the electric control panel.

In addition, the fixed ring structure 100 has a nozzle direction control device for freely controlling the water injection angle of the nozzle, and the illumination angle of the luminaire so as to illuminate the water sprayed by the nozzle direction control device freely An illumination direction control device is installed to control the power control panel. The electric control panel is connected to the nozzle direction control device and the illumination direction control device by a cable to supply power, and the controller controls the nozzle direction control device and the illumination direction. It is connected by cable to control device and applies communication signal.

According to the communication signal of the control unit, the nozzle direction control device rotates the nozzle in at least two directions or more to freely control the spraying direction, and the lighting direction control device can be produced in various colors and patterns according to the communication signal of the control unit. The lighting effect can be maximized by allowing the light to be irradiated in the left, right or up and down directions.

On the other hand, the fixed ring structure 100 is provided with a beam projector for displaying an image signal on the screen, the screen is formed of water discharged to the nozzle, the electrical control panel is connected to the beam projector by a cable to supply power The control unit is connected to the beam projector by a cable to apply a communication and image signal.

In addition, the fixing ring structure 100 is provided with a laser directing machine for displaying an image signal with a laser, the electrical control panel is connected to the laser directing cable to supply power, and the control unit is connected to the laser directing machine with a cable Communication and video signals.

The plurality of pipes may include a first pipe 110 installed on the fixed ring structure 100, a second pipe 211 installed on the first rotating ring structure 210, and the second rotating ring structure 220. It includes a third pipe 221 installed in. In addition, a pipe may be installed in the third rotating ring structure 230.

In addition, the plurality of pipes may be installed in the first rotating ring structure 210 to connect between the first rotating shaft 310 and the second rotating shaft 320, and the first and the second forming a different path The second connecting pipes 610 and 620 and the second rotating ring structure 220 are installed on the second connecting pipe 630 to connect the second rotating shaft 320 and the third rotating shaft 330. Include. At this time, the number of pipes is added or subtracted according to the number of rotating ring structure.

In addition, at least one supply pipe 40 extending from the pump 30 is provided to supply water supplied from the pump 30 to the first to third pipes 110, 211, and 221. .

Meanwhile, the first to third pipes 110, 211, and 221 may be installed along the exterior of the fixed ring structure 100 and the first and second rotating ring structures 210 and 220 to have a ring shape. .

In addition, at least one first nozzle 120, a second nozzle 213, and a third nozzle 223 connected to the first pipe 110, the second pipe 211, and the third pipe 221, respectively. This is installed. Accordingly, water supplied by the pump 30 is ejected through the first to third nozzles 120, 213, and 223 through the first to third pipes 110, 211, and 221.

In addition, the fixed ring structure 100 may be further provided with a multi-vector control nozzle driving device for controlling the first nozzle 120 in a multi-direction, the first and second rotating ring structure (210, 220) At least one jet nozzle, a flat nozzle and a fog nozzle may be further installed. By installing the multi-vector control nozzle drive device, a jet nozzle, a flat nozzle, a fog nozzle, and the like, various types of fountains can be produced.

On the other hand, the rotating shaft 300 is installed between the ring structure adjacent to each other, and includes a pair of first to third rotating shafts (310, 320, 330).

The first rotating shaft 310 is installed between the fixed ring structure 100 and the first rotating ring structure 210 to rotate the first rotating ring structure 210, the second rotating shaft 320 Is installed between the first rotary ring structure 210 and the second rotary ring structure 220 to rotate the second rotary ring structure 220, the third rotary shaft 330 is the second rotation Installed between the ring structure 220 and the third rotary ring structure 230, the third rotary ring structure 230 to rotate.

At this time, in the present embodiment, as the three rotary ring structures are installed, three rotary shafts are installed. However, since the number of the rotary shafts is selected according to the number of the rotary ring structures, the rotary shafts may be further installed. .

Meanwhile, first to third driving motors 410 to 430 are connected to the first to third rotation shafts 310 to 330, respectively, and the first to third rotation shafts 310 to 330 are respectively connected to the first to third rotation shafts. It is rotated in accordance with the driving of the three drive motors (410 ~ 430), to rotate the first to third rotary ring structure (210 ~ 230).

Therefore, a signal line and a power line are connected to the first to third rotation shafts 310 to 330 so as to be controlled by the first to third driving motors 410 to 430. For this purpose, a slip ring is provided. The signal line and the power line may be disposed in the slip ring.

The slip ring is installed on the first to third rotation shafts 310 to 330, and the other end of the first and second sleeves 312 and 313 or the first and second sleeves 312 to be described later. Even if the first or second sleeves 312 and 313 rotate inside the one of the 313, it is electrically connected.

In this case, a controller and an encoder may be installed in the first to third driving motors 410 to 430, respectively, and the controller controls the operation of the first to third driving motors 410 to 430, and the encoder. By feeding back the rotation angle of the first to third rotation axis (310 ~ 330) to the controller to enable accurate position control.

In this case, a controller and an encoder may be installed in the first to third driving motors 410 to 430, respectively, and the controller controls the operation of the first to third driving motors 410 to 430, and the encoder. By feeding back the rotation angle of the first to third rotation axis (310 ~ 330) to the controller to enable accurate position control.

In addition, the fixed ring structure 100 or the rotary ring structure 200 is provided with a reset sensor or switch for returning the rotary ring structure 200 to the initial position, the rotary ring structure 200 You can return to the initial position.

In addition, the first to third rotary shafts (310, 320, 33) are preferably installed in different directions, it can produce a variety of fountains.

According to the present embodiment, when viewed in a plan view, the first rotating shaft 310 is installed vertically, the second rotating shaft 320 is installed horizontally, and the third rotating shaft 330 is inclined approximately 45 °. Although installed to have, the direction of the first to third rotary shafts (310 to 330) is not limited to this, can be freely selected by those skilled in the art.

Referring to FIG. 3 in which the area A of FIG. 2 is enlarged, the first rotation shaft 310 is formed in a pair facing each other, and the first rotation shaft 310 is the fixed ring structure 100 or the first. A first housing 311 fixed to the rotary ring structure 210, first and second sleeves 312 and 313 installed inside the first housing 311, and the first and second sleeves 3. 312 and 313 may be a cylindrical hollow center.

At this time, one of the first and second sleeves 312 and 313 is a fixed sleeve fixed to the first housing 311, the other is a rotating sleeve rotatably installed in engagement with the fixed sleeve.

One end of each of the first and second sleeves 312 and 313 may be formed to be fitted to each other, and may be fitted into the first housing 311, and the first and second sleeves 312 and 313 may be fitted to each other. The other end which is not fitted to each other protrudes outside the first housing 311.

At this time, one end of the first and second sleeves 312 and 313 which are fitted to each other is open, and a space (hereinafter referred to as an “internal space”) inside the first and second sleeves 312 and 313. Is formed.

In addition, one of the other end of the first sleeve 312 and the other end of the second sleeve 313 is located on the fixing ring structure 100 side, the other is located on the first rotating ring structure 210 side. .

In this embodiment, the other end of the first sleeve 312 is located on the fixing ring structure 100 side, the other end of the second sleeve 313 is located on the first rotating ring structure 210 for example It is shown.

On the other hand, one end of the first and second sleeves 312 and 313 have a certain gap in the coupling portion to be fitted to each other, the sealing member 314 is located in the coupling portion. In this case, in order to provide a space in which the sealing member 314 is located, one or both of the first and second sleeves 312 and 313 are provided with a sealing groove 315 in which the sealing member 314 is seated. do. In the present exemplary embodiment, a sealing groove 315 is formed in the second sleeve 313.

One sealing groove 315 may be formed, but a plurality of sealing grooves 315 may be formed to improve airtightness. In this case, the number of the sealing members 314 may be the same as the number of the sealing grooves 315.

The sealing member 314 may be an O-ring, and in the case of a retainer, a Teflon ring, or a copper alloy material, the sealing member 314 may simultaneously perform a bearing function and a sealing function.

Each of the first and second sleeves 312 and 313 may be formed as one, but concentrically arranging sub sleeves having different diameters as in this embodiment may reduce interference during rotation, for example, The sleeve may be variously formed to have a diameter of 300 mm, 250 mm, 200 mm, 130 mm, and the like, and may be arranged concentrically with each other, and then fixed to each other by welding or the like.

According to the present embodiment, the first sleeve 312 is composed of three sub sleeves 312a, 312b, and 312c, and the second sleeve 313 is three subsleeves 313a, 313b, and 313c. Each of the sub sleeves 312a to 313c may have a cylindrical shape having a space formed therein (hereinafter, referred to as an “internal space”).

In this case, one end of the first and second sleeves 312 and 313 to be fitted is open, so that internal spaces between the sub sleeves coupled to each other are connected, and water may move through the internal spaces. In other words, the internal space serves as a movement passage of water.

At this time, it is preferable to weld from the sub sleeve having the smallest diameter at the time of welding, and also to form the sub sleeve having the smallest diameter the longest, and to form the sub sleeve having the largest diameter the shortest to have a step with each other. Can be formed.

The first housing 311 and the first and second sleeves 312 and 313 constituting the first rotation shaft 310 may be formed of a material that is prevented from corrosion, or may be formed of a material that is prevented from corrosion. .

In addition, since the first or second sleeves 312 and 313 must be rotated in the fixedly installed first housing 311, between the inner diameter of the first housing 311 and the outer diameter of the first sleeve 312. Alternatively, at least one bearing 316 is installed between the inner diameter of the first housing 311 and the outer diameter of the second sleeve 313. Here, the bearing 316 may be a sliding bearing, a ball bearing or a roller bearing.

In addition, a gap is provided between the sub sleeves 312a, 312b, and 312c constituting the first sleeve 312 and between the sub sleeves 313a, 313b, and 213c constituting the second sleeve 313. Spacer for constant may be further installed. Here, the spacing holder is formed of a plate material, may be installed in the longitudinal direction of the sub-sleeve, may be a spacing retaining plate installed at a predetermined interval, it may be a spacing retaining ring is installed in the form of a ring provided with a plurality of holes.

Meanwhile, holes 312a1 to 312c1 and 313a1 to 313c1 are formed at the other end of the first and second sleeves 312 and 313 which are not fitted to each other, and water is formed in the holes 312a1 to 312c1 and 313a1 to 313c1. The moving pipe is connected.

As in the present embodiment, the holes 312a1 to 312c1 and 313a1 to 313c1 are formed on the side surfaces of the first and second sleeves 312 and 313, specifically, the sub sleeves 312a to 312c and 313a to 313c. Can be formed. In some embodiments, the holes 312a1 to 312c1 and 313a1 to 313c1 may be formed by opening ends of the sub sleeves 312a to 312c and 313a to 313c in the longitudinal direction.

In this case, the pump 30 and the sleeve 312a to 312c1 formed in the sleeve positioned on the fixing ring structure 100 and the sub sleeves 312a to 312c of the first sleeve 312 in the present embodiment. Fastening pipes 317, 318, and 319 protruding to facilitate fastening with the supply pipe 40 to be connected are formed, and the fastening pipes 317, 318, and 319 are integrally formed with the sub sleeves 312a to 312c. After being formed as a star, it may be coupled to the sub sleeves 312 to 312 by screwing, welding, or the like.

On the other hand, a first connection is formed in each of the sleeves 313a1 to 313c1 formed in the sleeve located on the side of the first rotating ring structure 210 and the sub sleeves 313a to 313c of the second sleeve 313 in this embodiment. One end of the pipe 610, the second connecting pipe 620, and the second pipe 211 is connected.

In this case, as in the present embodiment, the first driving motor 410 connected to the first rotation shaft 310 may be installed on the first rotation ring structure 210, but may be installed on the fixed ring structure 100. It may be provided, or may be installed in the first housing 311.

In this case, when the first driving motor 410 is installed in the fixed ring structure 100, the first rotation ring structure 210 in which the first driving motor 410 is not installed may be rotated. Optionally, when the first driving motor 410 is installed in the first rotating ring structure 210, the first rotating ring structure 210 in which the first driving motor 410 is installed may be rotated.

That is, the rotary ring structure itself in which the first drive motor 410 is installed may be rotated, and the other rotary ring structure in which the first drive motor 410 is not installed may be rotated.

Referring to FIG. 4, in which the region B of FIG. 2 is enlarged, the second rotating shaft 320 is formed in a pair facing each other, and the first rotating ring structure 210 or the second rotating ring structure 220 is formed. A second housing 321 fixed to the first housing, a first central axis 322 installed in the second housing 321, third and fourth sleeves 323 and 324, and the first central axis 322. ) Is cylindrical, and the third and fourth sleeves 323 and 324 are cylindrical with a hollow central portion.

Of course, the first central axis 322 may be one cylindrical, but may be divided into two, each divided into two is to be fixed to the third and fourth sleeves (323, 324), In addition to the function of the axis of rotation, water pipes and cable pipes can also be used at the same time.

In this case, the third and fourth sleeves 323 and 324 are installed to surround the outside of the first central axis 322, and one of the third and fourth sleeves 323 and 324 is the second housing. A fixed sleeve fixed to 321, the other is a rotating sleeve rotatably installed in engagement with the fixed sleeve.

In this case, each of the third and fourth sleeves 323 and 324 surrounds another portion of the outer surface of the first central axis 322, and has a central point in the longitudinal direction of the first central axis 322. It may be in the form of surrounding the different parts by dividing roughly into two standards.

One end of each of the third and fourth sleeves 323 and 324 may be formed to be fitted to each other, and may be fitted into the second housing 321, and the third and fourth sleeves 323 and 324 may be connected to each other. The other end which is not fitted is protruded to the outside of the second housing 321, respectively. Similarly, both ends of the first central axis 322 also protrude out of the second housing 321.

At this time, one of the other end of the third sleeve 323 and the other end of the fourth sleeve 324 is located on the first rotary ring structure 210 side, the other is on the side of the second rotary ring structure 220 Located. In addition, one end of both ends of the first central axis 322 is located on the first rotary ring structure 210 side, the other end is located on the second rotary ring structure 220 side.

In the present embodiment, the other end of the third sleeve 323 is located on the second rotating ring structure 220 side, and the other end of the fourth sleeve 324 is located on the first rotating ring structure 210 side. This will be described as an example.

Meanwhile, a sealing member 325a is positioned at the coupling portion of the third and fourth sleeves 323 and 324, and the sealing member 325a is disposed at one or both of the third and fourth sleeves 323 and 324. The sealing groove 325b to be seated is formed. In the present exemplary embodiment, the sealing groove 325b is formed in the fourth sleeve 324.

Since the sealing member 325a and the sealing groove 325b have the same function as the sealing member 314 and the sealing groove 315 formed in the above-described first rotation shaft 310, a detailed description thereof will be omitted.

Each of the third and fourth sleeves 323 and 324 may be formed as one, but concentrically arranging sub sleeves having different diameters as in this embodiment may reduce interference during rotation.

According to the present embodiment, the third sleeve 323 is composed of two sub sleeves 323a and 323b, and the fourth sleeve 324 is composed of two sub sleeves 324a and 324b, Each of the sub sleeves 323a, 323b, 324a, and 324b may have a cylindrical shape having a space formed therein (hereinafter, referred to as an “internal space”).

 In this case, one end of the third and fourth sleeves 323 and 324 to be fitted is open, so that internal spaces between the sub sleeves coupled to each other are connected, and water may move through the internal spaces. In other words, the internal space serves as a movement passage of water.

The second housing 321, the first central shaft 322, and the third and fourth sleeves 323 and 324 constituting the second rotation shaft 320 may be formed of a material to prevent corrosion or may be treated to prevent corrosion. It is preferable to form from a material.

In addition, since the third or fourth sleeves 323 and 324 must be rotated in the fixedly installed second housing 321, between the inner diameter of the second housing 321 and the outer diameter of the third sleeve 323. Alternatively, at least one bearing 326 is installed between the inner diameter of the second housing 321 and the outer diameter of the fourth sleeve 324. Here, the bearing 326 may be a sliding bearing, a ball bearing or a roller bearing.

In addition, to maintain a gap between the sub sleeves 323a and 323b constituting the third sleeve 323 and the sub sleeves 324a and 324b constituting the fourth sleeve 324. A spacing zone may be further installed. Here, the spacing holder is formed of a plate material, may be installed in the longitudinal direction of the sub-sleeve, may be a spacing retaining plate installed at a predetermined interval, it may be a spacing retaining ring is installed in the form of a ring provided with a plurality of holes.

Meanwhile, holes 323a1, 323b1, 324a1, and 324b1 are formed at the other end of the third and fourth sleeves 323 and 324 which are not fitted to each other, and water is provided in the holes 323a1, 323b1, 324a1, and 324b1. The moving pipe is connected.

As in the present embodiment, the holes 323a1, 323b1, 324a1, and 324b1 are formed on the side surfaces of the first and second sleeves 323 and 324, specifically, the sub sleeves 323a, 323b, 324a and 324b. Can be formed. In some embodiments, the holes 323a1, 323b1, 324a1, and 324b1 may be formed by opening ends of the sub sleeves 323a, 323b, 324a, and 324b in the longitudinal direction.

In this case, each of the second holes is formed in the sleeve positioned on the side of the first rotating ring structure 210 and the holes 324a1 and 324b1 formed in the sub sleeves 324a and 324b of the fourth sleeve 324 in the present embodiment. The other end of the connector 620 and the first connector 610 is connected.

In addition, the third holes may be formed in the sleeves 323a1 and 323b1 formed in the sleeve positioned on the second rotating ring structure 220 and the sub sleeves 323a and 323b of the third sleeve 323 of the present embodiment. One end of the connecting pipe 630 and the third pipe 221 is connected.

As in the present embodiment, the second driving motor 420 connected to the second rotation shaft 320 may be installed on the second rotation ring structure 220, but may be installed on the first rotation ring structure 210. It may be provided, or may be installed in the second housing 321.

In this case, the second driving motor 420 may be installed in the second rotating ring structure 220 to rotate the first rotating ring structure 210 or to rotate the second rotating ring structure 220. And optionally installed in the first rotating ring structure 210 to rotate the first rotating ring structure 210 or to rotate the second rotating ring structure 220.

That is, the rotating ring structure itself in which the second driving motor 420 is installed may be rotated, and the other rotating ring structure in which the second driving motor 420 is not installed may be rotated.

Referring to FIG. 5, in which the region C of FIG. 2 is enlarged, the third rotating shaft 330 is formed in a pair facing each other, and the second rotating ring structure 220 or the third rotating ring structure 230 is formed. A third housing 331 fixed to the second housing 331, a second central axis 332 installed in the third housing 331, fifth and sixth sleeves 333 and 334, and the second central axis 332. ) Is cylindrical, and the fifth and sixth sleeves 333 and 334 may be formed in a cylindrical shape with an empty center.

In this case, the fifth and sixth sleeves 333 and 334 are installed to surround the outer surface of the second central axis 332, and one of the fifth and sixth sleeves 333 and 334 is the third. A fixed sleeve fixed to the housing 331, the other is a rotating sleeve that is rotatably installed in engagement with the fixed sleeve.

In this case, the fifth and sixth sleeves 333 and 334 respectively surround different portions of the second central axis 332 and are based on the central point in the longitudinal direction of the first central axis 332. It may be divided into approximately two parts to surround different parts.

One end of each of the fifth and sixth sleeves 333 and 334 may be formed to be fitted to each other, and may be fitted into the third housing 331, and the fifth and sixth sleeves 333 and 334 of the fifth and sixth sleeves 333 and 334 may be fitted together. The other ends not fitted to each other protrude to the outside of the third housing 331. Similarly, both ends of the second central axis 332 also protrude out of the third housing 331.

At this time, one of the other end of the fifth sleeve 333 and the other end of the sixth sleeve 334 is located on the second rotary ring structure 220 side, the other is on the third rotary ring structure 230 side Located. In addition, one end of both ends of the second central axis 332 is located on the second rotary ring structure 220 side, the other end is located on the third rotary ring structure 230 side.

In this embodiment, the other end of the fifth sleeve 333 is positioned on the third rotating ring structure 230, and the other end of the sixth sleeve 334 is located on the second rotating ring structure 220. This will be described as an example.

Meanwhile, a sealing member 335a is positioned at a coupling portion of the fifth and sixth sleeves 333 and 334, and the sealing member 335a is disposed at one or both of the fifth and sixth sleeves 333 and 334. The sealing groove 335b to be seated is formed. In this embodiment, the sealing groove 335b is formed in the sixth sleeve 334 as an example.

Since the sealing member 335a and the sealing groove 335b have the same function as the sealing member 314 and the sealing groove 315 formed in the first rotation shaft 310 described above, a detailed description thereof will be omitted.

Each of the fifth and sixth sleeves 333 and 334 may be formed as one, but concentrically arranging sub sleeves different from each other as in the present embodiment may reduce interference during rotation.

According to the present embodiment, the fifth sleeve 333 is composed of two sub sleeves 333a and 333b, and the sixth sleeve 334 is composed of two sub sleeves 334a and 334b.

In this case, each of the sub sleeves 333a, 333b, 334a, and 334b may have a cylindrical shape having a space formed therein (hereinafter, referred to as an “internal space”), and one end of the fitting may be opened to couple to each other. The inner spaces between the sub sleeves are connected. Therefore, when the internal space is formed, it can serve as a movement passage of water.

However, the inner space may not be formed when the fifth and sixth sleeves 333 and 334 do not need to serve as a movement passage of water.

The third housing 331, the second central axis 332, and the fifth and sixth sleeves 333 and 334 constituting the third rotation shaft 330 are formed of a material that prevents corrosion or are treated with corrosion protection. It is preferable to form from a material.

In addition, since the fifth or sixth sleeves 333 and 334 must be rotated in the fixedly installed third housing 331, between the inner diameter of the third housing 331 and the outer diameter of the fifth sleeve 333. Alternatively, at least one bearing 336 may be installed between the inner diameter of the third housing 331 and the outer diameter of the sixth sleeve 334. Here, the bearing 336 may be a sliding bearing, a ball bearing or a roller bearing.

In addition, a gap between the sub sleeves 333a and 333b constituting the fifth sleeve 333 and the sub sleeves 334a and 324b constituting the sixth sleeve 334 may be maintained. A spacing zone may be further installed. Here, the spacing holder is formed of a plate material, may be installed in the longitudinal direction of the sub-sleeve, may be a spacing retaining plate installed at a predetermined interval, it may be a spacing retaining ring is installed in the form of a ring provided with a plurality of holes.

Meanwhile, a hole 334b1 is formed at the other end of the sixth sleeve 334 which is not fitted, and the other end of the third connection pipe 630 is connected to the hole 334b1. In this case, the hole 334b1 may be formed on side surfaces of the sub sleeves 334a and 334b of the sixth sleeve 334. In the present embodiment, the hole 334b1 is formed in the subsleeve 334b located at the outermost part.

However, the holes 334b1 may not be formed when the fifth and sixth sleeves 333 and 334 do not need to serve as a water passage.

In addition, as in the present embodiment, the third driving motor 430 connected to the third rotating shaft 330 is installed inside the third rotating ring structure 230, and thus the third rotating ring structure 230 is formed. Can be rotated.

Referring to the process of spinning the ring structure fountain water with reference to Figures 6 to 9 showing the movement path of the water, the water stored in the tank 20 is moved along the supply pipe 40 by the pump 30 The first to third pipes 110, 211, and 221 are supplied to the first and third pipes 110, 211, and 221, and the supplied water is first to third nozzles 120 and 213 respectively installed on the first to third pipes 110, 211, and 221. , 223).

At this time, water is supplied to the first to third pipes 110, 211, and 221 through different paths and radiates. As shown in FIG. 6, the first pipe 110 is directly connected to the supply pipe 40. Supplied to the radiator through the first nozzle 120 or as shown in FIG. 7, the second pipe 211 is supplied to the second pipe 211 via the first rotation shaft 310 connected to the supply pipe 40 to the second pipe 211. Emitted through the nozzle 213, or is supplied to the third pipe 221 through the supply pipe 40, the first rotary shaft 310, the first connecting pipe and the second rotary shaft 320 as shown in FIG. , Is emitted through the third nozzle 223.

In this case, although water is supplied to the first to third pipes 110, 211, and 221 through different paths as described above, the process of supplying water does not occur independently but occurs simultaneously.

In addition, although not a path for supplying water to the first to third pipes 110, 211, and 221, the supply pipe 40, the first rotation shaft 310, the second connection pipe 620, and the second rotation shaft ( 320, a path through which the water moves to the third rotation shaft 330 through the third connecting pipe 630 is formed, and if the nozzles are formed in the second and third connecting pipes 620 and 630, various forms are provided. Can produce fountains.

Looking at the step of constructing a ring structure fountain according to the invention with reference to Figure 10, the ring structure fountain is a support construction step (S10) for installing the support in the space to install the fountain and the ring structure fixed to the support It can be installed through the fixing ring installation step (S20) for installing the, and the rotating ring structure installation step (S30) for installing the rotary ring structure inside the fixed ring structure.

At this time, in the rotating ring structure installation step, the rotating ring structure is sequentially installed from the outside in the fixed ring structure.

According to the present embodiment, three rotating ring structures are installed in the fixed ring structure, so that the rotating ring structure installation step includes installing the first rotating ring structure inside the fixed ring structure (S31). And a second rotating ring structure installation step (S32) for installing a second rotating ring structure inside the first rotating ring structure, and a third rotating ring for installing a third rotating ring structure inside the second rotating ring structure. It will include a structure installation step (S33).

At this time, the first rotary ring structure installation step (S31), the second rotary ring structure installation step (S32), and the third rotary ring structure installation step (S33) are respectively a fixed ring structure, the first rotary ring And installing a rotating shaft on the structure and the second rotating ring structure.

In addition, after the fixing ring structure installation step (S20), the first rotating ring structure installation step (S31), the second rotating ring structure installation step (S32), and the third rotating ring structure installation step (S33) at least One pipe, nozzle, cable, valve and light are installed.

As described above with reference to the drawings illustrating a ring structure having a rotating shaft according to the present invention, the present invention is not limited to the above embodiments and drawings, without departing from the gist of the invention claimed in the claims Various modifications can be made by those skilled in the art, and such modifications are within the scope of the appended claims.

10: support 20: tank
30: pump 40: supply pipe
100: fixed ring structure 110: first pipe
120: first nozzle 200: rotary ring structure
210: first rotating ring structure 211: second pipe
213: second nozzle 220: second rotating ring structure
221: third pipe 223: third nozzle
300: rotation axis 310: first rotation axis
311: first housing 312: first sleeve
312a, 312b, 312c: sub sleeve of the first sleeve
312a1, 312b1, 312c1, 313a1, 313b1, 313c1: holes
313: second sleeve
313a, 313b, 313c: sub sleeve of the second sleeve
314, 325a, 335a: sealing member
315, 325b, 335b: sealing groove 316, 326, 336: bearing
317, 318, 319: fastening pipe 320: second axis of rotation
321: second housing 322: first central axis
323: third sleeve
323a, 323b: sub sleeve of the third sleeve
323a1, 323b1, 324a1, 324b1: hole 324: fourth sleeve
324a, 324b: sub sleeve of the fourth sleeve
330: third axis of rotation 331: third housing
332: second central axis 333: fifth sleeve
333a, 333b: sub sleeve of the fifth sleeve
334: sixth sleeve
334a, 334b: sub sleeve of the sixth sleeve
334b1: hole 410: first drive motor
420: second drive motor 430: third drive motor
500: lighting unit 610: first connector
620: second connector 630: third connector

Claims (11)

A housing positioned between the fixed side structure and the rotating side structure, the housing being fixed to the fixed side structure or the rotating side structure;
A fixed sleeve fixed to the housing; And,
Rotatably installed in the housing, the rotating sleeve being coupled to the fixed sleeve,
One end of the stationary sleeve and the rotating sleeve is open and coupled to each other in the housing, and the other end of the stationary sleeve and the rotating sleeve respectively protrudes on both sides of the housing, one located at the stationary side structure, the other One axis of rotation is located on the rotating side structure. The method of claim 1,
And a drive motor installed in one of the fixed side structure, the rotating side structure, and the housing to rotate the rotating sleeve. delete The method of claim 1,
One end of any one of the fixed sleeve and the rotating sleeve includes a sealing groove for airtightness and a sealing member seated in the sealing groove,
At least one hole is formed at the other end of the fixed sleeve and the rotating sleeve protruding from the housing, the hole in which the water pipe is coupled, respectively. The method of claim 1,
The fixed sleeve and the rotating sleeve are formed by concentrically arranging sub sleeves having different diameters so that an inner space can be formed.
One end of the fixed sleeve and the rotary sleeve is coupled to the rotating shaft and the sub sleeves of the fixed sleeve and the sub sleeve of the rotary sleeve, respectively. The method of claim 1,
And a slip ring electrically connected to the other end of any one of the fixed sleeve and the rotary sleeve or the fixed sleeve, and even if the rotary sleeve rotates inside any one of the rotary sleeve. Fixed ring structures;
A rotating ring structure installed in the fixed ring structure; And
A housing positioned between the fixed ring structure and the rotary ring structure, the housing being fixed to the fixed ring structure or the rotary ring structure;
A fixed sleeve fixed to the housing; And
Rotatably installed in the housing, the rotating sleeve being coupled to the fixed sleeve,
One end of the stationary sleeve and the rotating sleeve is open and coupled to each other in the housing, and the other end of the stationary sleeve and the rotating sleeve respectively protrudes on both sides of the housing, one located at the stationary side structure, the other One ring structure having a rotation axis located in the rotating side structure. The method of claim 7, wherein
The ring structure having a rotating shaft is installed in any one of the fixed ring structure, the rotating ring structure, the housing, the drive motor for rotating the rotating sleeve. The method of claim 7, wherein
The rotary ring structure is provided with two or more of different diameter, each of the rotary ring structure is formed with a smaller outer diameter of the rotary ring structure than the inner diameter of the large rotary ring structure,
And a rotation axis between the large rotation ring structure and the small rotation ring structure, the rotation axis including at least one rotation axis such that the small rotation ring structure can rotate within the large rotation ring structure. The method of claim 7, wherein
The fixed ring structure is provided in a ring shape with a truss structure,
The lower portion coupled to the support for supporting the fixed ring structure is formed to have a wider width when viewed from the side, the upper portion is formed to have a narrower width formed narrower to the upper portion,
A ring structure having a rotating shaft whose cross-sectional shape has a wide width on the outer diameter side and a narrow width on the inner diameter side. The method of claim 7, wherein
Ring structure is installed directly adjacent to the fixed ring structure ring structure having a rotating shaft formed in the shape of a sphere.

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