KR20190012733A - Indoor Landscape Architecture System with Draining Function - Google Patents

Abstract

The present invention provides an indoor landscaping system performing a drainage function, which is capable of minimizing contamination induced by water leaked to the inside by automatically operating a pump to quickly flow water of a solution supply hose backward and drain the same when a damage occurs to the solution supply hose, and then water leakage occurs. The indoor landscaping system performing a drainage function comprises: a planting container in which soil or a medium for planting plants is installed; a solution supply hose which supplies water or nutrient solution and has an end toward the planting container clogged; a drip nozzle member which is installed in the solution supply hose and performs a dripping function for supplying water or nutrient solution toward the soil or medium in which the plants of the planting container are planted; a plurality of water leakage sensors which are installed on various positions of the solution supply hose to sense whether the water or nutrient solution flows; a pump which is installed in a drainage pipe branched at an end of a supply side of the solution supply hose and drains water inside the solution supply hose; a direction control valve which is installed on a part where the drainage pipe of the solution supply hose is branched; and a control device for controlling the pump and the direction control valve by receiving a sensing signal of the water leakage sensors.

Description

[0001] INDOOR Landscape Architecture System with Draining Function [0002]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to an indoor gardening system having a drainage function, and more particularly, to a gardening system having a drainage function. More particularly, when water leakage occurs due to damage or breakage of a liquid supply hose, water is quickly backwashed, To an indoor landscape system having a drainage function capable of minimizing pollution.

In general, indoor landscaping is achieved by using pots planted with flowers or trees.

In the case of indoor landscaping, care must be taken to prevent water supplied from the pollen to the bottom of the room from flowing out and contamination.

Korean Patent Laid-Open Nos. 10-2002-0032504, 10-2003-0041118, 10-2008-0103134, 10-2017-0068909, 10-0842539, 10-1187686 , No. 10-1187687, No. 10-1433598, No. 20-0288854, No. 20-0348057, No. 20-0436029, No. 20-2011-0003021, No. 20- 2016-0001316 discloses techniques for various indoor landscaping devices and structures.

Conventionally, in the case of devices and structures for indoor landscaping, various technologies are available for supplying water automatically, but techniques for preventing water from flowing out to the floor of a room are not sufficiently provided.

SUMMARY OF THE INVENTION The present invention has been made in view of the above problems, and it is an object of the present invention to provide a water supply hose for a water supply system in which when a water leakage occurs due to damage or breakage of a liquid supply hose, And an object of the present invention is to provide an indoor landscape system having a drain function capable of minimizing contamination.

The indoor landscape system having drainage function according to an embodiment of the present invention includes a planting container in which a soil or a medium for planting plants is installed, a liquid supply hose supplying water or nutrient solution, A drip nozzle member installed in the liquid supply hose and having a function of supplying water or nutrient solution toward the soil or the medium in which the plants of the planting tank are planted; A pump installed at a drain pipe branched at a supply side end of the liquid supply hose and discharging water inside the liquid supply hose; and a water supply pipe provided at a portion where a drain pipe of the liquid supply hose is branched And a control device for receiving the sensing signal of the leakage sensor and controlling the pump and the directional control valve The.

The direction control valve is configured to be switched in a direction of flowing toward the planting container of the liquid supply hose or in a direction of flowing toward the drain pipe from the liquid supply hose.

The leakage sensor may be a flow sensor, a pressure sensor, or the like.

The controller controls the direction of the directional control valve so as to move the water of the liquid supply hose or the nutrient solution toward the drain pipe while operating the pump in a water leakage state in which it is determined that water leakage occurs from the detection signal of the water leakage sensor .

The control device switches the direction of the directional control valve so that water or nutrient solution moves toward the planting container along the liquid supply hose in a steady state, and controls the pump to be in a stopped state.

Wherein the drip nozzle member has a tubular body having a bottom portion formed with an insertion portion to be inserted into a circumferential surface of the liquid supply hose and an upper surface assembled inside the body and having a long depressurization channel groove formed in a zigzag shape on an outer circumferential surface thereof A cap member coupled to an upper end of the body and having a drain hole formed on a circumferential surface thereof, an inner passage inserted into the inner tube, an upper end of the inner tube, It is also possible to include a valve plate to be installed.

In the indoor landscape system having drainage function according to the embodiment of the present invention, the controller determines whether or not the flow rate sensed by the water leakage sensor is greater than a normal amount discharged through the drip nozzle member, It is possible to operate the valve and the pump, so that it is possible to effectively prevent the water or the nutrient solution from flowing out due to damage or breakage of the liquid supply hose.

According to the indoor landscape system having the drainage function according to the embodiment of the present invention, it is possible not only to minimize leakage but also to supply only minimum amount of water or nutrients to the planting container through the dot nozzle member, And the like.

1 is a block diagram conceptually showing an indoor landscape system having drainage function according to an embodiment of the present invention.
2 is a front view of a point nozzle member in an indoor landscape system having a drainage function according to an embodiment of the present invention.
3 is an exploded perspective view showing a point nozzle member in an indoor landscape system having a drain function according to an embodiment of the present invention.
4 is a cross-sectional view showing a point nozzle member in an indoor landscape system having a drain function according to an embodiment of the present invention.
5 is a partially enlarged cross-sectional view illustrating an operation process of a valve plate of a dot nozzle member in an indoor landscape system having a drainage function according to an embodiment of the present invention.
6 is a block diagram showing another configuration of a directional control valve and a pump in an indoor gardening system having a drainage function according to an embodiment of the present invention.
7 is a side view showing another example of the connection state of the liquid supply hose and the drop nozzle member in the indoor landscape system having the drainage function according to the embodiment of the present invention.

DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENTS Next, preferred embodiments of an indoor landscaping system having drainage function according to the present invention will be described in detail with reference to the drawings.

The present invention can be embodied in various forms and is not limited to the embodiments described below.

Hereinafter, for the purpose of clearly illustrating the present invention, a detailed description of parts that are not closely related to the present invention is omitted, and the same or similar components are denoted by the same reference numerals throughout the entire description of the present invention, .

1, an indoor landscape system having a drain function according to an embodiment of the present invention includes a planting container 100, a liquid supply hose 200, a dot nozzle member 300, A detection sensor 500, a pump 600, a directional control valve 700, and a control device 900.

Inside the planting container 100, a soil or a medium for planting plants is installed.

The liquid supply hose 200 supplies water or nutrient solution, and the end of the side of the planting container 100 is closed.

The liquid supply hose 200 is connected to a liquid supply source for supplying water or a nutrient solution at a predetermined pressure.

The water supply source may be a water pipe, a tank containing water or a nutrient solution, and a pump for supplying water or a nutrient solution, and may be implemented in various configurations.

A filter 290 may be provided on the liquid supply source side of the liquid supply hose 200 to filter foreign substances contained in water or nutrient solution and prevent the foreign matter contained in the liquid supply hose 200 from flowing into the liquid supply hose 200.

The drip nozzle member (300) is installed in the liquid supply hose (200).

The drip nozzle member 300 is configured to have a dripping function of supplying water or nutrients to the soil or the medium of the planting container 200.

2 to 4, the drip nozzle member 300 includes a tubular body 310 (see FIG. 2) in which an insertion portion 314 to be inserted into and coupled to the circumferential surface of the liquid supply hose 200 is formed in the bottom surface portion A channel tube 330 which is assembled inside the body 310 and has an upper surface blocked with a depressurizing channel groove 334 formed in a zigzag shape on the outer surface of the body 310; A cap member 380 in which a drain hole 388 is formed on a circumferential surface of the flow tube 330, an inner tube 350 inserted into the flow tube 330, And a valve plate 370 installed between the upper surfaces of the valve plate 370.

The insertion portion 314 of the body 310 is formed in an arrowhead shape and is configured to be easily inserted into an engagement hole formed in the angled supply hose 200.

The portion of the insertion portion 314 coupled with the liquid supply hose 200 is formed in a dimension larger than the size of the engagement hole formed in the liquid supply hose 200, The water or the nutrient solution of the liquid supply hose 200 can be prevented from leaking through the joint portion.

An inlet hole 315 through which the water or nutrient solution of the liquid supply hose 200 flows is formed in the bottom surface of the insertion portion 314 of the body 310.

The cap member 380 is formed at the lower end thereof with an assembly part 384 inserted into the upper end of the body 310.

An engaging portion 316 is formed at an upper end of the body 310 to engage the assembling portion 384 of the cap member 380.

The assembling part 384 and the engaging part 316 are formed with concave and convex engageable with each other so as not to be easily separated from the body 310 in a state where the cap member 380 is engaged.

By doing so, it is possible to effectively prevent the water or the nutrient solution from leaking through the joining part by firmly adhering the joining part between the cap member 380 and the body 310.

The plurality of drain holes 388 of the cap member 380 are formed in a small size to control the discharge of water or nutrient solution in a small amount and prevent the soil or foreign matter from flowing into the interior of the cap member 380 Do.

The drain hole 388 of the cap member 380 is preferably formed at a symmetrical position for convenience of assembly.

It is preferable that the depressurizing flow path groove 334 formed in the flow path tube 330 is formed so as to have a long flow path from the upper end portion to the lower end portion toward the upper end portion.

A first through hole 335 and a second through hole 336 are formed in the upper end of the flow tube 330 so as to be connected to both ends of the pressure reducing flow groove 334.

The first through hole 335 is formed on the bottom surface of the valve plate 370 and the second through hole 336 is formed on the top surface of the valve plate 370.

An outlet hole 338 is formed in the upper surface of the flow tube 330.

When the flow path tube 330 and the valve plate 370 are constructed as described above, the valve plate 370 is rotated by the pressure of the water or the nutrient solution flowing through the inlet hole 315 of the body 310, And the water or nutrient solution is supplied to the inner peripheral surface of the body 310 through the first through hole 335 and the inner circumferential surface of the reduced pressure channel groove 331 of the flow tube 330 And the second through hole 336 is formed above the valve plate 370 so that water or nutrient solution in the flow tube 330 flows toward the second through hole 336 Leakage is prevented.

The water inside the flow path tube 330 is moved through the first through hole 335 and the water or nutrient solution passing through the pressure reducing flow path groove 334 flows through the second through hole 334, Flows into the space between the valve plate 370 and the upper surface of the flow tube 330 through the through hole 336 and moves toward the cap member 380 through the outflow hole 338.

When the flow path tube 330 is formed with grooves on the upper surface of the flow path tube 330, the flow path connected from the second through hole 336 to the outflow hole 338 may be formed on the upper surface of the flow path tube 330. The water or the nutrient solution flows from the second through hole 336 to the outflow hole 338 even in the state of being in close contact with the upper surface.

The water or nutrient solution supplied from the liquid supply hose 200 flows out through the first through hole 335 and then passes through the second through hole 336 through the pressure reducing flow groove 334, And flows toward the cap member 380 through the outflow hole 338. The cap member 380 is formed of a resin material.

A connection hole 355 is formed in the end of the inner cylinder 350 in the thickness direction and a communication groove 354 is formed in the outer circumferential surface of the inner cylinder 350 along the circumference in a state of being connected to the connection hole 355 .

The water or nutrient solution supplied from the liquid supply hose 200 flows out through the connection hole 355 and then flows through the communication hole 354 to the first through hole 335 to the pressure-decreasing channel groove 334 side.

The communication groove 354 is formed by being positioned so as to communicate with the connection hole 355 and the first through hole 335.

The communication groove 354 and the connection hole 355 are formed at positions corresponding to the upper end and the lower end of the inner cylinder 350 when the inner tube 350 is assembled to the flow tube 330 The convenience of assembly is greatly improved.

When the drip nozzle member 300 is constructed as described above, water or nutrient liquid of a predetermined pressure flowing from the liquid supply hose 200 through the inlet hole 315 of the body 310 flows into the pressure reducing channel groove 334, The pressure drops sharply and is discharged through the drain hole 388 of the cap member 380, so that the droplet is dropped and the supply is performed in a dropwise dropping manner.

When the supply of the water or the nutrient solution from the liquid supply source to the liquid supply hose 200 is stopped, the pressure transmitted from the liquid supply hose 200 to the inside of the flow path tube 330 decreases, 370 are also reduced and the flow rate of the water or nutrient solution flowing into the second through holes 336 to the outflow holes 338 is temporarily increased and the pressure reducing flow grooves 334, It is also possible that cleaning is performed while foreign matters or small solid matter in the flow path between the two through holes 336 and the outflow holes 338 are discharged together.

The distance between the upper surface of the inner cylinder 350 on which the valve plate 370 is provided and the bottom surface of the upper surface of the flow tube 330 is set larger than the thickness of the valve plate 370 And the bottom surface edge of the upper surface portion of the flow path tube 330 may be inclined.

The valve plate 370 is maintained in an unstable state at the initial stage of filling the inner cylinder 350 with water or nutrient solution having a predetermined pressure flowing into the inlet hole 315 of the body 31 .

However, as the water or nutrient solution gradually fills the inner cylinder 350, the valve plate 370 starts to be deformed by the pressure of the water or nutrient solution, and the valve plate 370, the inner cylinder 350, A clearance is generated between the flow tubes 330 and a part of the water or the nutrient solution flows through the generated gaps and flows out through the outflow holes 338 formed on the upper surface of the flow tube 330.

In the state where the water or the nutrient solution flows out as described above, the flow of the fluid is rapidly formed and the foreign matter is discharged, and a cleaning operation is performed.

When the inner tube 350 is sufficiently filled with water or a nutrient solution, the valve plate 370 is kept in a state of being in close contact with the bottom surface of the upper surface portion of the flow tube 330 by pressure, The water or nutrient solution filled in the inner tube 350 moves through the connection hole 355 of the inner tube 350 and the first through hole 335 of the flow tube 330.

When the water flowing into the inlet hole 315 of the body 31 is blocked, the pressure inside the inner cylinder 350 is lowered, and the valve plate 370 is separated from the bottom surface of the upper surface portion of the flow tube 330 The water or the nutrient solution flows out through the crevices which are falling off, and the discharging and cleaning work of the foreign matter is performed.

The dripping nozzle member 300 is configured as described above to remove foreign matter at the moment when water or nutrient solution is supplied and at the moment when the supply is blocked and water or nutrient solution is supplied to the pressure- 334, it is possible to prevent foreign matter from clogging the pressure-reducing flow path groove 334. [

As shown in FIG. 1, the water leakage sensor 500 is installed at various positions of the liquid supply hose 200 to detect whether water or nutrient solution is flowing.

The leakage sensor 500 may be a flow sensor, a pressure sensor, or the like.

In the case where the leak sensor 500 is constituted by a pressure sensor, it is also possible to detect a change in the pressure inside the liquid supply hose 200 to detect the flow rate.

The pump 600 is installed in a drain pipe 800 branched from a supply side end of the liquid supply hose 200.

The pump 600 is installed to drain the water inside the liquid supply hose 200.

The directional control valve 700 is installed at a portion where the drain pipe 800 of the liquid supply hose 200 is branched.

The controller 900 controls the pump 600 and the directional control valve 700 by receiving a sensing signal from the leakage sensing sensor 500.

The directional control valve 700 is configured to selectively switch the flow direction of the liquid supply hose 200 toward the planting container 100 or the direction of flow from the liquid supply hose 200 toward the drain pipe 800.

The controller 900 controls the pump 600 to operate while the water in the liquid supply hose 200 or the nutrient solution in the liquid supply hose 200 is in a leak state, And the direction control valve 700 is switched so as to move toward the drain pipe 800.

The control device 900 switches the direction of the directional control valve 700 so that water or nutrient solution moves toward the planting container 100 along the liquid supply hose 200 in a normal state, As shown in FIG.

When water or nutrient solution is supplied to the liquid supply hose 200, the water sensor 500 senses the flow of water or nutrient solution.

The flow rate or flow rate of the water or nutrient solution supplied to the liquid supply hose 200 rapidly increases in the initial stage and the flow rate or the flow rate of the nutrient solution supplied to the liquid supply hose 200 increases When the water or nutrient solution reaches the end, it becomes a stabilization step in which the flow rate or the flow rate is very slow.

Since the water or nutrient flowing through the liquid supply hose 200 moves by the amount discharged through the drip nozzle member 300, the flow rate or the flow rate sensed by the water leakage sensor 500 in a steady state is very low .

On the other hand, in a leakage state where a hole is formed in the liquid supply hose 200 to generate leakage, the amount of water or nutrient solution flowing through the liquid supply hose 200 increases, and the leakage detection sensor 500 The change in the sensed flow velocity or flow rate greatly increases.

Water or nutrient solution is supplied to the liquid supply hose 200 from a change in the signal sensed by the water leakage sensor 500 and the liquid is supplied to the liquid supply hose 200 The reference value of the flow velocity or the flow rate change amount is set so that it is possible to determine whether or not leaks occur.

For example, if the length and cross-sectional area of the liquid supply hose 200 and the pressure of the water or nutrient solution supplied to the liquid supply hose 200 are known, the entire length of the liquid supply hose 200 is filled with water or nutrient solution If the signal sensed by the water leakage sensor 500 is greater than the set value of the normal state even after the initial supply time has elapsed, the control device 900 determines that the water leakage has occurred do.

If the number of the dot nozzle members 300 installed in the liquid supply hose 200 is known, the amount of water or nutrient solution discharged through the dot nozzle member 300 can be known, It is possible to set the reference value of the flow rate or the flow rate of the water or nutrient solution supplied through the controller 200 to the control device 900.

For example, in the controller 900, a flow rate or a flow rate exceeding a certain ratio (for example, 20% or 30%, etc.) relative to the reference value of the flow rate or flow rate in the steady state is detected by the leak detection sensor 500), it is possible to determine that the water leakage state is determined.

The control device 900 may be configured to be controlled using an app or the like mounted on a smart phone.

The directional control valve 700 may be constructed using a three-way valve.

6, the direction control valve 700 is configured by using a four-way valve, a pump 600 is provided between the direction control valve 700 and the liquid supply source, and the liquid supply source and the pump And an opening / closing valve 750 may be provided between the first and second valves 600 and 600.

The liquid supply hose 200 is connected to one of the four ports of the directional control valve 700 and the drain pipe 800 is connected to the other port and the pump 600 And a drain connection pipe 850 connected to the suction port of the pump 600 is connected to the other port.

The directional control valve 700 configured as described above is configured such that a flow path is formed so that water or nutrient solution supplied from the discharge port of the pump 600 moves toward the liquid supply hose 200 in a steady state, The flow path between the connection pipe 850 is shut off and the water or nutrient solution in the liquid supply hose 200 flows to the drain connection pipe 850 in the leakage state, And a drain pipe 800 connected to the connection pipe 250. The drain pipe 800 and the connection pipe 250 are connected to each other.

Closing valve 750 in a steady state, and operates to close the on-off valve 750 in a leak state.

In the normal state, water or nutrient solution supplied from the liquid supply source is supplied to the liquid supply hose 200 at a constant pressure as the pump 600 operates.

As the pump 600 is operated in the water leakage state, the water in the liquid supply hose 200 flows into the suction port of the pump 600 through the drain connection pipe 850 and is discharged through the discharge port. And is drained through the connection pipe 250 and the drain pipe 800.

The water or nutrient flowing through the liquid supply hose 200 is moved by an amount discharged through the drip nozzle member 300 so that the flow velocity or flow rate sensed by the water leakage sensor 500 is very low in a steady state.

On the other hand, in a leakage state where a hole is formed in the liquid supply hose 200 to generate leakage, the amount of water or nutrient solution flowing through the liquid supply hose 200 increases, and the leakage detection sensor 500 The change in the sensed flow velocity or flow rate greatly increases.

According to the indoor landscape system having the drain function according to an embodiment of the present invention, when the flow rate or flow rate of water or nutrient solution detected by the water leakage sensor 500 in the controller 900 reaches the leakage state It is possible to switch the direction control valve 700 to discharge water or nutrient solution from the liquid supply hose 200 toward the drain pipe 800 and control the pump 700 to operate It is possible to quickly discharge the water or nutrient solution from the liquid supply hose 200 through the drain pipe 800.

Therefore, it is possible to minimize the outflow of water or nutrients into the room when the liquid supply hose 900 is damaged or broken.

When the pressure of the liquid supply hose 200 becomes lower than a predetermined pressure, the pump 700 is operated to supply water or nutrient solution, and the liquid supply hose 200 The operation of the pump 700 can be stopped.

With such a configuration, it is possible to minimize the consumption of water or nutrient solution, and to minimize the excessive pressure applied to the liquid supply hose 200.

7, the drip nozzle member 300 is not provided on the circumferential surface of the liquid supply hose 200 but is connected to the liquid supply hose 200, It may be installed in a state of being inserted into the end of the branch pipe 280.

The branch mechanism 270 has an inlet connected to the liquid supply hose 200 and a plurality of outlets to which the branch pipe 280 is coupled.

With the above arrangement, it is possible to arrange and install one dot nozzle member 300 in each planting container 100.

According to the indoor landscaping system having the drain function according to the embodiment of the present invention configured as described above, it is possible to prevent the outflow of water as much as possible. Therefore, even in a place where an electric appliance, So that indoor landscaping can be performed.

For example, indoor landscaping can be carried out by planting plants on the roof of a lamp installed on the ceiling.

Furthermore, it is possible to plant the plant in a place where furniture or the like made of wood or the like is damaged by absorbing water to perform indoor landscape.

While the present invention has been described in connection with certain exemplary embodiments thereof, it will be understood by those skilled in the art that various changes and modifications may be made without departing from the spirit and scope of the invention as defined in the appended claims. And is also within the scope of the present invention.

100 - food container, 200 - liquid supply hose, 250 - connector, 270 - minute instrument
280-branch tube, 290-filter, 300-point nozzle member, 310-body
314 - insertion portion, 315 - inlet hole, 316 - coupling portion, 330 - flow tube
334 - Pressure reducing channel groove, 335 - First through hole, 336 - Second through hole, 338 - Outlet hole
350 - inner tube, 354 - communicating groove, 355 - connecting hole, 370 - valve plate, 380 - cap member
384 - Assembly, 388 - Drain hole, 500 - Leak detection sensor, 600 - Pump
700-directional control valve, 750-opening and closing valve, 800-drain pipe, 850-drain connection pipe
900 - Control device

Claims (5)

A planting container in which a soil or a medium for planting plants is installed inside,
A liquid supply hose supplying water or a nutrient solution,
A drip nozzle member installed in the liquid supply hose and having a dripping function for supplying water or a nutrient solution toward a soil or a medium in which the plants of the planting tank are planted,
A plurality of water leakage sensors installed at various positions of the liquid supply hose to detect whether water or nutrient solution flows,
A pump installed at a drain pipe branched at a supply-side end portion of the liquid supply hose and draining water inside the liquid supply hose,
A direction control valve installed at a portion where a drain pipe of the liquid supply hose is branched,
And a control device for receiving the detection signal of the water leakage sensor and controlling the pump and the directional control valve. The method according to claim 1,
Wherein the directional control valve is configured to switch between a direction in which the directional control valve flows toward the planting container of the liquid supply hose or a direction in which the liquid flows from the liquid supply hose toward the drain pipe. The method according to claim 1,
The directional control valve is constructed using a four-way valve,
A pump is provided between the directional control valve and the liquid supply source,
An open / close valve is provided between the liquid supply source and the pump,
The liquid supply hose is connected to one of the four ports of the directional control valve and the drain pipe is connected to the other port and the connection pipe connected to the discharge port of the pump is connected to the other port, And a drain connection pipe connected to the suction port side of the pump is connected to the remaining one port,
Wherein the direction control valve operates in a state in which a flow path is formed so that water or nutrient solution supplied from a discharge port of the pump moves toward the liquid supply hose in a steady state and a flow path between the drain pipe and the drain connection pipe is shut off,
The directional control valve operates in a state in which water or nutrient solution of the liquid supply hose flows to the drain connection pipe in a leak state, and a flow path is formed between a connection pipe connected to the discharge port of the pump and the drain pipe ,
Wherein the on / off valve operates to open in a steady state, and has a drain function to operate in a leak state. The method according to claim 1,
The control device is configured to operate the pump in a water leakage state and switch the direction of the directional control valve such that water or nutrient solution of the liquid supply hose moves toward the drain pipe,
And in the steady state, the direction of the directional control valve is switched so that water or nutrient solution moves toward the planting container along the liquid supply hose, and the pump is controlled to be in a stopped state. The method according to claim 1,
Wherein the drip nozzle member has a tubular body having a bottom portion formed with a coupling portion to be inserted into and coupled with a circumferential surface of the liquid supply hose and a top surface having a reduced pressure channel groove formed in a zigzag shape on an outer circumferential surface thereof, A cap member coupled to an upper end of the body and having a drain hole formed on a circumferential surface thereof, an inner passage inserted into the inner tube, an upper end of the inner tube, And a valve plate to be installed,
The insertion portion of the body is formed in an arrowhead shape,
Wherein a portion of the inserting portion which is engaged with the liquid supply hose is formed to have a size larger than a size of a coupling hole formed in the liquid supply hose,
An inlet hole through which the water or nutrient solution flows in the liquid supply hose is formed in the bottom surface of the insertion portion of the body,
A lower portion of the cap member is formed with an assembling portion to be inserted into the upper end of the body,
A coupling portion to which the assembly portion of the cap member is coupled is formed at an upper end of the body,
Wherein the assembling portion and the engaging portion are formed with concave and convex engages with each other,
Pressure flow path groove formed in the flow path tube is formed so that one flow path is formed long toward the upper end side from the upper end side toward the lower end side,
A first through hole and a second through hole are formed in an upper end portion of the flow tube so as to penetrate the outer circumferential surface so as to be connected to both ends of the pressure-
Wherein the first through hole is formed to be positioned on the bottom surface side of the valve plate,
The second through hole is formed on the upper surface side of the valve plate,
An outflow hole is formed in the upper surface of the flow tube,
Wherein a connection hole is formed through the inner end of the inner tube in a thickness direction,
Wherein a communication groove is formed in the outer circumferential surface of the inner cylinder along a circumference in a state of being connected to the connection hole,
And the communication groove has a drain function for establishing a position so as to communicate with the connection hole and the first through hole.

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