KR101006196B1 - Channel switching apparatus for fountain - Google Patents

Abstract

PURPOSE: A channel switching apparatus for a fountain is provided to switch a channel by an air control method, thereby drastically increasing durability and energy efficiency. CONSTITUTION: A channel switching apparatus for a fountain includes an input channel, the first and second output channels, a body, and a control value(200). Liquid flows into the input channel. The liquid is drained through the first and second output channels. The first and second control channels are formed in the body. The control value switches a draining direction of the liquid by selectively supplying inhaled air to one of the first and second control channels.

Description

Channel switching apparatus for fountain using air control

The present invention relates to a fountain flow path switching device, and more particularly to a fountain flow path switching device capable of efficiently performing the water supply and shutoff to the fountain nozzle in an air control method.

Generally, fountains are installed for landscaping of gardens, parks, squares and lakes. Fountains sprinkle water in various forms to provide citizens with beautiful scenery and comfort. The fountain is provided with a water tank, an underwater pump, piping, a fountain nozzle, and various valves, and various types of fountains can be realized according to the arrangement of the fountain nozzles. In addition, the dynamic beauty of the fountain can be realized by moving the fountain nozzle or by periodically blocking the water supply to the fountain nozzle.

Such fountain is mainly used in the responsive solenoid valve for water supply and shut off to the fountain nozzle. That is, in the fountain according to the prior art, the water pump is continuously operated, the water supply and shutoff to the fountain nozzle is made in accordance with the opening and closing of the solenoid valve installed in the pipe. However, as the opening and closing of the solenoid valve is instantaneously, a sudden pressure change occurs in the pipe, and the responsiveness is deteriorated due to an overload of the solenoid valve. In addition, the fountain according to the prior art takes a constant water pressure for each fountain nozzle by the submersible pump, when some flow paths are blocked by the solenoid valve, there is a problem that the height of the fountain becomes irregular because the water pressure applied to the other fountain nozzles increases.

The prior art for solving such problems is the Republic of Korea Patent No. 0787036. The three-way solenoid valve according to the prior art selectively discharges water introduced through the inlet port to the outlet port connected to the fountain nozzle or the drain port connected to the water tank according to the ON-OFF state. At this time, the flow path is switched and a constant hydraulic pressure is applied to each fountain nozzle. The valve responsiveness is improved by bypassing a part of the water discharged from the outlet or the drain so that the valve can be opened and closed quickly.

However, the conventional three-way solenoid valve also has a structure of directly operating the valve body using the magnetic force generated in the solenoid. In the solenoid valve of this type, since the valve body directly opens and closes the flow path, the water pressure received by the valve body is large. This is a major obstacle to improving the durability of the solenoid valve. In addition, there is a problem in that power consumption is large because the magnetic force value for operating the valve body is large.

In addition, the three-way solenoid valve according to the prior art is a variety of foreign matter contained in the water of the water tank is easily blocked the internal flow path, there is a serious problem of failure.

The present invention has been proposed to solve the problems of the prior art as described above, to provide a flow path switching device for a fountain that can greatly improve the durability and energy efficiency by switching the flow path in the air control method.

Another object of the present invention is to provide a fountain flow path switching device that can further improve the durability by preventing the introduction of various foreign matters.

The object of the present invention as described above, the liquid of a predetermined pressure is introduced through the one end of the input port 112, the other end of the input channel 110 is formed with a nozzle hole 114 for amplifying the flow rate of the liquid, and one end First and second output channels 120 and 130 communicating with the input channel 110 in an intersecting state to form a Y-shaped flow path and discharging liquid through the respective output ports 122 and 132 at the other ends. And first and second ends of which one end is coplanar with the first and second output channels 120 and 130 so as to communicate with the crossed ends of the first and second output channels 120 and 130, respectively. A body 100 in which control passages 152 and 154 are formed; And a control valve 200 for selectively switching the discharge direction of the liquid by selectively supplying the sucked air to any one of the first and second control flow paths 152 and 154. It can be achieved by a receiving flow channel switching device.

In addition, the cross-sectional area of the flow path of the first output channel 120 and the second output channel 130 is preferably 0.3 to 1 times the cross-sectional area of the flow path of the input channel 110.

The other end of the first output channel 120 is formed parallel to the longitudinal direction of the input channel 110, and the other end of the second output channel 130 is perpendicular to the longitudinal direction of the input channel 100. It is preferably formed.

The control valve 200 has an inflow path 212 through which air is sucked, a branch chamber 214 in communication with the inflow path 212, and one end in communication with the branch chamber 214. A flow passage member 210 having first and second discharge passages 216 and 218 communicating with the first and second control passages 152 and 154, respectively; And an actuating lever 226 installed in the center chamber 222 so that the center chamber 222 communicating with the branch chamber 218, the coil 224 surrounding the center chamber 222, and one end thereof are in the branch chamber 214. ) And a gripping means 228 for applying one end of the other end of the operating lever 226 to one end of the operating lever 226 to block one of the first and second discharge passages 216 and 218. And a solenoid mechanism 220 having one end of the operating lever 226 blocking the other of the first and second discharge paths 214 and 216 when electricity is applied to the coil 224. do.

In addition, a first connection path 242 for communicating the inflow path 212 of the flow path member 210 and the air suction pipe 300 communicating with the atmosphere is formed, and the first and second of the flow path member 210 are formed. The connection member 240 is further provided with second and third connection paths 244 and 246 communicating the discharge passages 216 and 218 and the first and second control passages 152 and 154, respectively.

And, the guide jaw 116 is formed in the middle of the input channel 110, the filter 400 is inserted and supported by the guide jaw 116; And the input channel 110 is one side is opened for the installation and inspection of the filter 400, the transparent inspection window 500 for opening and closing the open one side; is further provided.

As described above, the fountain flow path switching device according to the present invention selectively supplies air to the first control passage or the second control passage according to the ON-OFF state of the control valve, and forms a pressure difference in the branch chamber. To convert the flow path. That is, the control valve according to the present invention is to interrupt the flow of gas, not liquid, so that the energy consumption is low, durability and response can be improved. In addition, the mechanical valve configuration is omitted in the inner flow path formed in the body has the advantage that the durability of the flow path switching device is greatly improved.

In addition, the fountain flow path switching device according to the present invention is provided with a filter in the input channel to filter out various foreign matters to prevent the internal flow path and the fountain nozzle from being blocked. In addition, the fluid flow of the internal flow path is stabilized, thereby improving the reliability of the flow path switching device according to the present invention.

In addition, the present invention can check the contamination state of the filter through the inspection window, it is possible to conveniently clean or replace the filter at the appropriate time.

Although the present invention has been described in connection with the above-mentioned preferred embodiments, it will be readily apparent to those skilled in the art that various other modifications and variations are possible without departing from the spirit and scope of the invention. Are all within the scope of the appended claims.

1 is a front side perspective view of the fountain flow path switching apparatus according to an embodiment of the present invention.
Figure 2 is a rear side perspective view of the fountain flow path switching apparatus according to an embodiment of the present invention.
Figure 3 is a vertical sectional view of the body according to the present invention.
4 is a sectional view of a control valve according to the present invention;
5A and 5B are cross-sectional views for explaining the operation of the fountain flow path switching device according to an embodiment of the present invention.

Hereinafter, preferred embodiments of the present invention will be described in detail with reference to the accompanying drawings. In adding reference numerals to components of each drawing, the same reference numerals are used for the same components as much as possible even though they are shown in different drawings.

First, with reference to the accompanying drawings will be described the configuration of the water flow channel switching device using the air control according to an embodiment of the present invention.

1 is a front side perspective view of the fountain flow path switching apparatus according to an embodiment of the present invention, Figure 2 is a rear side perspective view. As shown in FIG. 1 and FIG. 2, water flows in through the input port 112 formed at the bottom of the fountain flow channel switching device 10 according to the present invention, and the first output port 122 or the first formed at the upper side thereof is formed. 2 is output through the output port (132). Fountain flow path switching device 10 according to the present invention is composed of a body 100, a control valve 200, a filter 400, the inspection window 500.

Body 100 is made of a corrosion-resistant metal material such as synthetic resin or stainless steel for waterproof function. In addition, a predetermined flow path is formed inside the body 100. At this time, the body 100 is preferably integrally molded by a method such as casting, injection molding for the airtightness of the inner passage. On the other hand, a plurality of fastening holes 105 are formed in the body 100 for installation of the flow path switching device 10.

Figure 3 is a vertical sectional view of the body according to the present invention. As shown in FIG. 3, the internal flow path of the body 100 includes an input channel 110, first and second output channels 120 and 130, and first and second control channels 152 and 154.

The input channel 110 is connected to a pipe (not shown) connected to an underwater pump (not shown). At this time, the input channel 110 is introduced into the pressurized water at a predetermined pressure in accordance with the designed height of the fountain. The input channel 110 is provided with an input port 112 at a lower end thereof, and a nozzle hole 114 for amplifying the flow rate of water introduced at the upper end thereof is formed. In addition, the filter guide jaw 116 is formed in the middle of the input channel 110 to insert the filter 400 which will be described later. At this time, the input channel 100 is open to the front side for the installation and inspection of the filter 400.

As shown in FIG. 3, the first output channel 120 and the second output channel 130 communicate with the nozzle hole 114 of the input channel 110 in a state where the lower ends thereof cross each other. An output port 122 and a second output port 132 are provided. Specifically, the first and second output channels 120 and 130 communicate with the input channel 110 with the lower ends intersecting to form a Y-shaped flow path. At this time, the first and second output channels 120 and 130 intersect to form a crossover chamber 142 indicated by a dotted line in FIG. 3. The first and second output channels 120 and 130 are branched from the branch edge 144. The cross chamber 142 preferably has a diameter at the lower end of the nozzle hole 114 larger than the diameter of the nozzle hole 114. In addition, the channel cross-sectional area size of each of the output channels 120 and 130 is preferably 0.3 to 1 times the channel cross-sectional area of the input channel 110. That is, the cross-sectional area of the flow channel of each output channel 120, 130 is smaller than that of the input channel 110, so that the discharge speed of each output channel 120, 130 is larger than the inflow rate of the input channel 110. .

On the other hand, the upper end of the first output channel 120 having the first output port 122 is preferably formed in parallel with the longitudinal direction of the input channel 110, as shown in FIG. This is for connecting the fountain nozzle (not shown) to the first output port 122. The upper end of the second output channel 130 having the second output port 132 may be formed perpendicular to the longitudinal direction of the input channel 110. This is for connecting the pipe (not shown) connected to the water tank (not shown) to the second output port 132. That is, the water discharged through the second output port 132 is returned to the water tank.

Alternatively, a fountain nozzle (not shown) may be connected to the second output port 132. In this case, the upper end of the second output channel 130 may be formed in parallel with the longitudinal direction of the input channel 110 like the first output channel 120. That is, the fountain nozzles may be installed in pairs in the first and second output channels 120 and 130 to diversify the fountain shape.

As illustrated in FIG. 3, one end of the first control channel 152 and the second control channel 154 is located on the same plane as the first and second output channels 120 and 130, and the first and second output channels are disposed on the same plane. The ends of the channels 120 and 130, that is, the lower ends of the cross chambers 142, communicate with each other. The other ends of the first and second control passages 152 and 154 are respectively formed to the rear side of the body 100. On the other hand, the diameter of the first and second control passages (152, 154) is preferably at least 3mm or more for smooth air control.

The control valve 200 is a three-way valve to switch the flow path to the first output channel 120 or the second output channel 130 by selectively supplying air to the first and second control flow paths (152, 154). . The process of converting the euro will be described later in detail.

As shown in FIG. 2, the control valve 200 according to the present exemplary embodiment includes a flow path member 210, a solenoid mechanism 220, and a connection member 240, and is fixed to the support 250 and the body 100. Is installed on the rear side. In this case, the connection member 240 connects the flow path member 210 and the first and second control flow paths 152 and 154 described above.

4 is a cross-sectional view of the control valve 200 according to the present invention. As shown in FIG. 4, the flow path member 210 includes an inflow path 212, a branch chamber 214, and first and second discharge paths 216 and 218. That is, the air flowing through the inflow path 212 is discharged through the first and second discharge path 216 through the branch chamber 214. In this case, the flow path member 210 is preferably the inlet side of the inlet passage 212 and the outlet side of the first and second discharge passages (216, 218) are directed downward for connection with the connecting member (240).

As shown in FIG. 4, the solenoid mechanism 220 includes an insulator 221 having a rectangular parallelepiped shape, and a central chamber 222 communicating with the branch chamber 218 is formed perpendicular to the insulator 221. The coil 224 is wound around the central chamber 222. And, the operating lever 226 made of a magnetic material is located in the branch chamber 214 of the flow path member 210, the lower end is installed in the center chamber 222 in the form of a lever. That is, the support protrusion 226a formed in the center chamber 222 and the groove 226b formed in the operation lever 226 are engaged with each other, and the first holding means 227 actuates the support lever 226 from the opposite side of the support protrusion 226a. It has a structure to pressurize. At this time, the second gripping means 228 exerts an elastic force on one side of the upper end of the operating lever 226 so that the lower end of the operating lever 226 is in close contact with the inlet side of the second discharge path 218. Accordingly, the first discharge path 216 is opened, and the second discharge path 218 is in an initial state (OFF) that is closed. On the other hand, the first holding means 227 is installed in the first installation groove 227a communicating with the lower side of the center chamber 222, the second holding means 228 is made of the first communication with the upper side of the center chamber 222 2 is installed in the installation groove 228a.

In the solenoid mechanism 220 having the above structure, the operation lever 226 is driven by the magnetic force generated as the electricity is applied to the coil 224. That is, the lower end of the operation lever 226 is in close contact with the inlet side of the first discharge path 216 to open the second discharge path 218 and at the same time block the first discharge path 216. Then, when the magnetic force is extinguished, the operation lever 226 is restored to the initial state (OFF).

On the other hand, since the solenoid mechanism 220 is an electrical component, it is preferable to waterproof the outer surface of the insulator 221. In addition, as shown in FIG. 4, the intermediate film 230 is installed between the flow path member 210 and the solenoid mechanism 220 to surround the lower end of the operation lever 226. The interlayer 230 is made of a flexible material such as rubber or synthetic resin. The interlayer 230 protects the solenoid mechanism 220 from dust, moisture, and the like contained in the air, and serves to seal the first and second discharge paths 216 and 218 in an airtight manner.

The connection member 240 may include a first connection path 242 connecting the air suction pipe 300 and the inflow path 212 of the flow path member 210 shown in FIG. 2, and the first and second control flow paths 152. Second and third connection paths 244 and 246 are formed to communicate the other end of 154 and the first and second discharge paths 216 and 218 of the flow path member 210, respectively.

Atmospheric suction pipe 300 is a pipe (not shown) exposed to the atmosphere is connected to the end. Therefore, air is naturally sucked into the inflow path 212 of the flow path member 210 by the atmospheric pressure without a separate air injection device, and is supplied to the first and second control flow paths 152 and 154 formed in the body 100. .

The filter 400 is installed in the filter guide jaw 116 formed in the input channel 110 as shown in FIGS. 1 and 3. In this case, the filter 400 may be spaced apart from the nozzle hole 114 by a predetermined distance so as not to disturb the fluid flow passing through the nozzle hole 114. The filter 400 prevents the internal flow path from being blocked by filtering various foreign matters contained in the water, and facilitates the fluid flow in the internal flow path.

The inspection window 500 is for checking the contamination state of the filter 400. According to the present embodiment, the first and second support members 512 and 514 are fastened to the lower part of the body 100 to install the inspection window 500, and the inspection window 500 is connected to the first support member 512. It is hinged and installed. On the other hand, a gasket 520 is provided on the inner circumference of the inspection window 500, and is in close contact with the sealing surface 513 formed on the first support member 512 to prevent water from leaking. And, the inspection window 500 is preferably made of a transparent material so that the state of the filter 400 with the naked eye.

The inspection window 500 is closed by fastening the lock screw 532 to the screw hole 534 formed in the first support member 512. In addition, when the filter 400 is polluted and needs cleaning or replacement, the inspection window 500 may be opened by releasing the locking screw 532. In this way, the inspection window 500 makes the installation and management of the filter 400 easy and convenient.

[Operation of the present invention]

5A and 5B, the operation of the fountain flow channel switching device according to the present invention will be described based on the process of switching the flow path using air control. Solid arrows shown in FIGS. 5A and 5B indicate the flow of water, and dotted arrows indicate the supply direction of air by the control valve 200.

In the water flow channel switching device 10 according to the present invention, water that is pressurized and transported through a pipe (not shown) is introduced into the input channel 110 by an underwater pump (not shown). At this time, various foreign substances are filtered by the filter 400, and the flow velocity is amplified while passing through the nozzle hole 114.

5A shows the fluid flow when the control valve 200 is in the initial state (OFF). At this time, the initial state of the control valve 200 refers to the state shown in FIG. That is, the second discharge path 218 is closed and the first discharge path 216 is in an open state. Therefore, air is sucked in through the inflow path 212 under the action of atmospheric pressure, and the air flows into the first control flow path 152 formed in the body 100 via the first discharge path 216 and the second connection path 244. Is supplied. As a result, the pressure at the right side of the branch chamber 142 in which the first control passage 152 is formed is greater than the pressure at the left side. As a result, a relatively low pressure is formed at the left side of the branch chamber 142, and the amplified fluid flow F (hereinafter, 'amplified fluid flow') passing through the nozzle hole 114 is formed in the first output channel 120. Is deflected toward At this time, the amplifying fluid flow F forms a boundary layer by the frictional force of the left wall surface 142a of the branch chamber 142. In addition, as the amplifying fluid flow F is deflected to the left, a low pressure bubble B is formed near the left edge of the end of the nozzle hole 114, which accelerates the formation of the boundary layer described above. At this time, as the boundary layer is formed, the amplifying fluid flow F flows smoothly while being attached to the left wall surface 142a. The amplifying fluid flow F passes through the first output channel 120 and the first output port 122 and is finally injected from a fountain nozzle (not shown).

5B shows the fluid flow when the control valve 200 is in the ON state. At this time, the operation lever 226 shown in FIG. 4 closes the first discharge path 216. Accordingly, air is supplied to the second control passage 154 through the second discharge passage 218 and the third connection passage 246, and a low pressure is formed at the right side of the branch chamber 142. Then, the amplification fluid flow F is deflected toward the second output channel 130 by the above-described operating principle, and is conveyed to the tank (not shown) via the second output port 132.

In this way, the flow path switching device 10 according to the present invention is to switch the flow path in accordance with the ON-OFF state of the control valve 200, the intermittent injection is made in the fountain nozzle (not shown) to implement the dynamic beauty of the fountain Can be. At this time, the ON-OFF of the control valve 200 is preferably converted to about 5Hz or more in order to realize the effective dynamic of the fraction.

10: flow path switching device 100: body
110: input channel 112: input port
114: nozzle hole 116: filter guide jaw
120: first output channel 122: first output port
130: second output channel 132: second output port
142: cross chamber 144: branch edge
152: first control channel 154: second control channel
200: control valve 210: flow path member
212: inlet 214: branch chamber
216: first discharge path 218: second discharge path
220: solenoid mechanism 221: insulator
222: center chamber 224: coil
226: operation lever 226a: support protrusion
226b: groove 227: first fingering means
227a: first mounting groove 228: second holding means
228a: second installation groove 230: interlayer
240 connection member 242 first connection path
244: second connection 246: third connection
250: support member 300: atmospheric suction tube
400: filter 500: inspection window
512: first support member 513: sealing surface
514: second support member 520: gasket
532: locking screw 534: screw hole

Claims (7)

A liquid having a predetermined pressure flows through one end of the input port 112, and an input channel 110 having a nozzle hole 114 for amplifying the flow velocity of the liquid at the other end thereof;
The first and second output channels communicating with the input channel 110 in a state where one end is crossed to form a Y-shaped flow path and discharging the liquid through the respective output ports 122 and 132 at the other end ( 120, 130),
First and second ends of which one end is coplanar with the first and second output channels 120 and 130 so as to communicate with the opposite ends of the first and second output channels 120 and 130, respectively. A body 100 in which control passages 152 and 154 are formed; And
In the control valve 200 to switch the discharge direction of the liquid by selectively supplying the suctioned air to any one of the first and second control passages (152, 154),
The control valve 200,
An inlet passage 212 through which the air is sucked;
Branch chamber 214 in communication with the inlet path 212,
One flow path member 210 having first and second discharge passages 216 and 218 communicating with the branch chamber 214 and the other end communicating with the first and second control passages 152 and 154, respectively. ); And
A central chamber 222 in communication with the branch chamber 218,
A coil 224 surrounding the central chamber 222,
An operation lever 226 installed at the center chamber 222 with one end at the branch chamber 214,
By applying an elastic force to one side of the other end of the operating lever 226, one end of the operating lever 226 to the gripping means 228 to block any one of the first and second discharge paths (216, 218) Composed, and
And a solenoid mechanism 220 having one end of the operation lever 226 blocking the other of the first and second discharge passages 214 and 216 when electricity is applied to the coil 224. Fountain flow path switching device using the air control characterized in that. The method of claim 1,
The flow path cross-sectional area of the first output channel (120) and the second output channel 130 is 0.3 ~ 1 times the cross-sectional area of the flow path of the input channel (110). The method of claim 1,
The other end of the first output channel 120 is formed parallel to the longitudinal direction of the input channel 110, and
The other end of the second output channel 130, the flow path switching device for fractions using air control, characterized in that formed in the vertical direction of the input channel (100). delete The method of claim 1,
A first connection path 242 is formed to communicate the inflow path 212 of the flow path member 210 and the air suction pipe 300 in communication with the atmosphere, and
Second and third connection passages 244 and 246 communicating first and second discharge passages 216 and 218 of the passage member 210 and the first and second control passages 152 and 154, respectively. Fountain flow path switching device using the air control, characterized in that the connection member 240 is further provided. The method of claim 1,
A guide (400) formed at an intermediate portion of the input channel (110) and inserted into and supported by the guide (116); And
The input channel 110 has one side open for the installation and inspection of the filter 400, the transparent inspection window 500 for opening and closing the open one side; air control, characterized in that further provided Fountain flow path switching device used. A liquid having a predetermined pressure flows through one end of the input port 112, and an input channel 110 having a nozzle hole 114 for amplifying the flow velocity of the liquid at the other end thereof;
The first and second output channels communicating with the input channel 110 in a state where one end is crossed to form a Y-shaped flow path and discharging the liquid through the respective output ports 122 and 132 at the other end ( 120, 130),
First and second ends of which one end is coplanar with the first and second output channels 120 and 130 so as to communicate with the opposite ends of the first and second output channels 120 and 130, respectively. A body 100 in which control passages 152 and 154 are formed;
An inflow passage 212 through which air is sucked, a branch chamber 214 in communication with the inflow passage 212, and one end in communication with the branch chamber 214, and the other end of the first and second control passages ( A flow path member 210 having first and second discharge paths 216 and 218 communicating with 152 and 154, respectively;
A center chamber 222 in communication with the branch chamber 218, a coil 224 surrounding the center chamber 222, and one end of the branch chamber 214 installed in the center chamber 222. By applying an elastic force to the lever 226 and the other end of the operation lever 226, one end of the operation lever 226 blocks one of the first and second discharge paths 216 and 218. And a solenoid configured to be provided with a gripping means 228 and one end of the actuating lever 226 blocks the other of the first and second discharge passages 214 and 216 when electricity is applied to the coil 224. Instrument 220,
An intermediate film 230 of a flexible material installed between the flow path member 210 and the solenoid mechanism 220 to surround the lower end of the operation lever 226,
A first connection path 242 is formed to communicate the inflow path 212 of the flow path member 210 and the air suction pipe 300 communicating with the atmosphere, and the first and second discharge paths of the flow path member 210 are formed. And a connection member 240 formed with second and third connection passages 244 and 246 for communicating the first and second control passages 152 and 154 with the second and third control passages 216 and 218, respectively. A control valve (200) for selectively switching the discharge direction of the liquid by selectively supplying air sucked through (300) to any one of the first and second control passages (152, 154);
A guide (400) formed at an intermediate portion of the input channel (110) and inserted into and supported by the guide (116); And
The input channel 110 has one side open for installation and inspection of the filter 400, the inspection window 500 of the transparent material for opening and closing the open one side; and
The channel cross-sectional area of the first output channel 120 and the second output channel 130 is 0.3 to 1 times the channel cross-sectional area of the input channel 110,
The other end of the first output channel 120 is formed parallel to the longitudinal direction of the input channel 110, the other end of the second output channel 130 is perpendicular to the longitudinal direction of the input channel 100. Fountain flow path switching device using the air control, characterized in that formed to.

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