KR20220016379A - Microbubble generator for plant cultivation - Google Patents

Abstract

The present invention relates to a microbubble generation apparatus for cultivating a plant, which is improved to generate and use microbubbles as plant cultivation water. According to the present invention, the microbubble generation apparatus comprises: an external suction hose installed outside a case and connected to a suction head provided to suck water to transfer the water to the inside of the case; an internal suction pipe installed inside the case and connected to the external suction hose; a circulation pump forcedly sucking the water through the internal suction pipe; a pressure tank applying a constant pressure so that gas-liquid transferred through the circulation pump is discharged to the outside; a gas-liquid transfer pipe connecting the circulation pump and the upper part of the pressure tank to transfer the gas-liquid to the pressure tank; a gas-liquid discharge pipe connected to one side of the lower part of the pressure tank and installed inside the case to transfer the gas-liquid discharged from the pressure tank; a microbubble ejection device installed at an end part of the gas-liquid discharge pipe and installed inside the case to generate microbubbles from the gas-liquid introduced through the gas-liquid discharge pipe; an ejection hose connected to the microbubble ejection device and installed to be connected to the outside of the case to eject the microbubbles to the outside of the case; and an ejection head connected to an end part of the ejection hose so that the microbubbles ejected through the ejection hose are directly used as plant cultivation water.

Description

Microbubble generator for plant cultivation

The present invention relates to a device for generating microbubbles for plant cultivation, and more particularly, to an improved device for generating microbubbles for plant cultivation by generating microbubbles so that they can be used as water for plant cultivation.

In general, a bubble refers to a state in which a liquid encapsulates gas and swells to form hollow droplets, and is often referred to as a bubble.

In addition, microbubbles or microbubbles mean bubbles with a particle size of 2 μm or less. It is made up of particles so fine that it is only a level.

As a prior document related to these microbubbles, Patent Publication No. 10-0801092 discloses a 'microbubble generator and a bathtub system using the same, and Patent Publication No. 10-0748580 discloses a 'microbubble generator'. , Patent Publication No. 10-2007-0002300 discloses a 'bubble generating device for a bathtub'.

When describing the schematic structure of a general bubble generator for a bathtub with reference to FIG. 1 , the general bubble generator for a bathtub 10 is a bathtub water suction unit 20 for sucking the water filled in the bathtub (B) as shown in the figure. , a circulation pump 32 for generating power to be sucked in the water in the bathtub through the bathtub water suction unit 20, a gas-liquid mixing unit 34 for sucking air into the water sucked into the circulation pump 32 and mixing it; A pressure tank 36 for allowing the gas-liquid transferred through the circulation pump 32 to be ejected by applying a constant pressure, a gas-liquid transfer pipe 38 and pressure to connect the circulation pump 32 and the pressure tank 36 to move the gas-liquid It is connected to the tank 36 and configured to include a bubble discharge unit 40 for generating microbubbles while discharging gas and liquid into the bathtub.

On the other hand, the bathtub water suction unit 20 of the bubble generator 10 for the bathtub is composed of a suction head 22 and a suction hose 24 for sucking the water filled in the bathtub B, and the bubble generator 10 is a gas-liquid It consists of a discharge hose 44 and a microbubble jet head 42 that generates microbubbles while discharging gas and liquid.

And the above-described circulation pump 32, gas-liquid mixing unit 34, pressure tank 36 and gas-liquid transfer pipe 38 of the bubble generator 10 for the bathtub is a case that becomes the body of the bubble generator 10 for the bathtub ( 30) While properly disposed and assembled inside, the bathtub water suction unit 20 and the bubble discharge unit 40 are assembled to be exposed to the outside of the case 30 .

That is, in the process of the user using the bubble generator 10 for the bathtub, the suction head 22 of the bathtub water suction unit 20 and the microbubble jet head 42 of the bubble discharge unit 40 are placed in the bathtub (B). In the immersed state, by operating a switch installed on the outside of the case 30, air bubbles are generated.

When the user turns on the switch of the bubble generator 10 for the bathtub, the water in the bathtub is sucked through the bathtub water suction part 20 while the circulation pump 32 is driven while the gas-liquid mixing part 34 In this, the air introduced through the air intake pipe 34a and the sucked water are mixed. The gas-liquid (gas and liquid) mixed in this way becomes a bubble state through forced circulation of the circulation pump 32 and stays at a predetermined pressure or more in the pressure tank 36 . In addition, the gas-liquid in the pressure tank 36 is changed into fine bubbles of finer particles in the process of being jetted into the bathtub B through the microbubble jet head 42 of the bubble discharge unit 40 .

That is, the flow rate of the gas-liquid passing through the gas-liquid discharge hose 44 of the bubble discharging unit 40 rapidly passes through the sieve installed in the microbubble jet head 42, the pressure plate formed with the pressure hole, and one or more meshes. As the speed increases, fine-sized bubbles are formed, and as a result, fine-grained bubbles are ejected.

On the other hand, plant cultivation water containing ultra-fine bubbles (bubbles) having a diameter of micro-nano has a very long time to exist in water compared to general bubbles, and maintains an equilibrium state in the aqueous solution according to the size of the bubbles. Oxygen air bubbles exist in the liquid for a long period of time to facilitate the supply of oxygen in the underground part and promote the growth of various plants.

In addition, the ultrafine bubble surface has a -charge, and it plays a role in inducing high quality by reducing the nitrogen content of nitrate (NO3-) by relatively increasing the absorption of + ions in the culture medium.

As such, ultra-fine bubbles help plant growth and furthermore, when ozone gas is used to create ultra-fine bubbles, they remain in a parallel state in a special aqueous solution and exist for a long time in ozone micro-nano water. When micro-nano water is used, it can be applied to overall agriculture as a substitute for pesticides.

Accordingly, a supply device for plant cultivation water containing micro-bubbles that can supply water for plant cultivation containing micro-nano bubbles necessary for producing eco-friendly agricultural products has been devised.

The supply device for plant cultivation water containing ultrafine bubbles designed as described above is disclosed in Korean Patent Publication No. 10-1235366 (February 14, 2013, registered).

However, the supply device for plant cultivation water containing ultrafine bubbles of the above-mentioned registered patent has a very complicated configuration and is expensive, and it is difficult for an operator to carry it, so that it is not easy to use for plant cultivation such as plant cultivation.

The present invention was created to solve the above problems, and it is an object of the present invention to provide an apparatus for generating microbubbles for plant cultivation, which has a very simple configuration and is easy to carry so that it can be used for plant cultivation. That is, an object of the present invention is to provide an apparatus for generating microbubbles for plant cultivation that can promote the growth of various plants.

The apparatus for generating microbubbles for plant cultivation of the present invention for achieving the above object,

case;

a suction head installed outside the case and provided to suck water;

an external suction hose connected to the suction head so that water can be transferred into the case;

an internal suction pipe installed inside the case and connected to the external suction hose;

a circulation pump for forcibly sucking water through the internal suction pipe;

a pressure tank for discharging the gas-liquid transferred through the circulation pump to the outside by applying a constant pressure;

a gas-liquid pipe connected to the circulation pump and an upper part of the pressure tank so that the gas-liquid is transferred to the pressure tank;

a gas-liquid discharge pipe connected to one side of the lower side of the pressure tank and installed inside the case to transport the gas-liquid discharged from the pressure tank;

a micro-bubble ejection device installed at the end of the gas-liquid discharge pipe and installed inside the case to convert the gas-liquid introduced through the gas-liquid discharge pipe into microbubbles;

a jet hose connected to the microbubble jetting device, installed connected to the outside of the case, and jetting microbubbles to the outside of the case; and

a jet head installed connected to the end of the jet hose so that the microbubbles blown out through the jet hose are directly used as water for plant cultivation;

It is characterized in that it includes.

In the present invention, the pressure tank comprises: a body; and a collision plate installed on one side of the body and configured to collide while the gas-liquid falls into the supplied pressure tank. A discharge hole is formed.

In the present invention, the collision plate is installed to be inclined at a predetermined angle inside the body, and the collision plate is installed to be inclined at 45° to 60°.

In the present invention, the gas-liquid discharge hole is formed in a circular shape.

In the present invention, an air vent is provided on the upper portion of the body to automatically discharge air when the pressure exceeds a certain level inside the body to maintain a constant pressure.

In the present invention, the microbubble ejection device, the main body; a pipe connection part formed at the rear of the main body and connected to the gas-liquid discharge pipe; a cover installed in front of the main body and having a plurality of outlet holes to eject microbubbles generated in the main body to the external ejection hose, and a hose coupling part coupled to the external ejection hose; a cylindrical member installed in the body to one side of the pipe connection part; a housing installed in the cylindrical member; and a bubble diffusion member installed in the front of the housing to diffuse microbubbles and formed with a diffusion plate protruding a predetermined length to the rear, wherein a surface-processed portion is formed in front of the diffusion plate at a predetermined angle.

According to an embodiment of the present invention, all constituent devices are mounted inside the case to facilitate portability, a function of a pressure tank is added, a microbubble ejection device is provided inside the case, and the pressure tank is located at the right rear end. By installing it, the microbubble effect was maximized.

In addition, water is supplied to the outside of the case and it is provided only with a configuration that allows microbubbles to be ejected, and the configuration is very simple and very easy to carry, so that the use of water for plant cultivation is maximized, and the operation is very easy.

1 is a block diagram showing the configuration of a general micro-bubble generator for a bathtub.
Figure 2 is an external perspective view showing the external configuration of the microbubble generator for plant cultivation according to the present invention.
Figure 3 is an internal cross-sectional configuration view of Figure 2;
4 is an external perspective view showing an external configuration of the pressure tank of FIG. 3;
5 is a plan cross-sectional view showing the internal configuration of the pressure tank of FIG.
6 is a cross-sectional view of the microbubble ejection device of FIG.
7 is a detailed cross-sectional view of the configuration of the main part of FIG.

Hereinafter, preferred embodiments according to the present invention will be described in detail with reference to the accompanying drawings.

2 is an external perspective view showing the external configuration of the apparatus for generating microbubbles for plant cultivation according to the present invention.

And FIG. 3 is an internal cross-sectional configuration diagram of FIG. 2 is shown.

In addition, FIG. 4 is an external perspective view showing the external configuration of the pressure tank of FIG. 3 , and FIG. 5 is a plan cross-sectional view showing the internal configuration of the pressure tank of FIG. 4 .

And Figure 6 is a cross-sectional view of the microbubble ejection device of Figure 3 is shown, Figure 7 is a detailed cross-sectional view of the configuration of the main part of Figure 6 is shown.

2 to 7 , the microbubble generating device 200 for plant cultivation according to the present invention includes a case 201 and a suction head 212 installed outside the case 201 to suction water. ), an external suction hose 214 connected to the suction head 212 to allow water to be transferred into the case 201, and an external suction hose 214 installed inside the case 201, ) connected to the internal suction pipe 215, the circulation pump 220 for forcibly sucking water through the internal suction pipe 215, and the circulation pump 220 for sucking and mixing air with the water sucked into the inside It is configured to include a gas-liquid mixing pipe 230 and a pressure tank 240 for discharging the gas-liquid transferred through the circulation pump 220 to the outside by applying a constant pressure.

In addition, the microbubble generating device 200 for plant cultivation according to the present invention connects the circulation pump 220 and the upper part of the pressure tank 240 so that the gas-liquid is transferred to the pressure tank 240 . ), a priming water tank 260 provided on one side of the gas-liquid pipe 250 to store water, and a pressure tank 240 connected to the lower side of the pressure tank 240 and installed inside the case 201 ) A gas-liquid discharge pipe 275 for discharging the gas-liquid inside, and a microbubble jetting device 300 installed at the end of the gas-liquid discharge pipe 275 and installed inside the case 201, and the microbubble jetting device 300 Connected to and installed on the outside of the case 201, and the ejection hose 272 for ejecting microbubbles to the outside of the case 201, and the ejection hose 272 is connected to the end of the ejection hose 272. It is configured to include an ejection head 274 that allows the ejected microbubbles to be used directly as water for plant cultivation.

And the microbubble generating device 200 for plant cultivation according to the present invention is installed on one side of the internal suction pipe 215 to detect water sucked into the internal suction pipe 215. An electronic controller 280 for turning off the driving of the purifying pump 220, and a circulating pump ( 220) is configured to include a check valve 290 to keep the water filled state between the priming bucket 260 and the priming bucket 260 even when the suction pressure is stopped according to the operation stop.

In addition, the gas-liquid mixing pipe 230 of the microbubble generating device 200 for plant cultivation according to the present invention is provided with an air suction pipe 232 through which air is sucked.

In addition, the electronic controller 280 stops the operation of the circulation pump 220 when no more water is sucked from the internal suction pipe 215 .

Accordingly, although not shown in the drawings, the electronic controller 280 is provided with a detection sensor for detecting water or pressure flowing inside the internal suction pipe 215 .

In this way, the electronic controller 280 determines that the suction of water is not made when water or pressure is not sensed for a certain period of time through the detection of the flowing water or pressure inside the internal suction pipe 215 through the detection sensor, and the circulation pump Stop the operation of 220 to prevent idling.

And the check valve 290 of the microbubble generating device 200 for plant cultivation according to the present invention prevents the reverse flow of the sucked water.

Accordingly, even when the suction pressure does not act according to the stop of the operation of the circulation pump 220, a state in which water is always filled between the priming bucket 260 and the check valve 290 is maintained.

Therefore, by ensuring that water is always present in a certain section inside the microbubble generating device 200 for plant cultivation to minimize the rate of idling when the circulation pump 220 is re-operated, there is no fear of being exposed to overload of the circulation pump 220 do.

In addition, the pressure tank 240 of the microbubble generating device 200 for plant cultivation according to the present invention, as shown in FIGS. 4 and 5, a body 241 substantially composed of a rectangular parallelepiped, and this body 241 A collision plate 246 is provided on one side of the inner 241a to cause a collision while the gas-liquid falls into the supplied pressure tank 240 and the inner 241a is provided.

The collision plate 246 is installed to be inclined at a predetermined angle to the inside 241a of the body 241 .

The angle of the collision plate 246 is preferably installed at an angle of 45° to 60° to facilitate installation of the collision plate 246 and obtain maximum collision force.

In addition, the four side edges of the collision plate 246 are fixed by welding (W) to the inner side 241a of the body 241 .

In addition, a plurality of gas-liquid discharge holes 246a are formed in the collision plate 246 so that the dropped gas-liquid falls back to the lower portion of the collision plate 246 .

The gas-liquid discharge hole 246a is preferably formed in a circular shape that is easy to discharge gas and liquid and is easy to form.

However, the shape of the gas-liquid discharge hole 246a is not limited to a circular shape as shown in FIG. 5, but may be formed in a polygonal shape.

In addition, as shown in FIG. 5 , the gas-liquid discharge holes 246a are preferably regularly formed at regular intervals to facilitate gas-liquid discharge.

In addition, an air vent 245 is provided on the upper portion of the body 241 so that air is automatically discharged when the pressure exceeds a certain level in the interior 241a of the body 241 to maintain a constant pressure.

In addition, as shown in FIGS. 6 and 7 , the microbubble ejection device 300 may be ejected in a state of finer bubbles in the process in which the gas liquid in the bubble state is ejected, for example, into water for plant cultivation such as plant cultivation. A pressure plate 370 and a seal ring 380 installed on the front and rear surfaces of the pressure plate 370 are assembled in the housing 314 .

And the main body 310 of the microbubble ejection device 300 is made of an empty cylindrical shape inside so that internal parts can be assembled, and a cover 320 having a plurality of discharge holes 322 through it is assembled in front of it. , the rear end of the gas-liquid discharge pipe 275 is provided with a pipe connection part 312 is connected and assembled.

In addition, a housing 314 is provided inside the main body 310 , and a screw 314a for screwing the bubble diffusion member 330 is formed on the inner periphery of the housing 314 .

And the inside of the housing 314 is made of a structure directly connected to the inside of the pipe connection portion (312).

In addition, the housing 314 is installed in the cylindrical member 316 .

In addition, the bubble diffusion member 330 is installed to allow the components in the housing 314 to be assembled in a stable state even under high pressure and to spread microbubbles more widely while passing through the components.

For this purpose, a screw 332 for screwing to the screw 314a formed on the inner periphery of the housing 314 is formed on the outer peripheral surface of the bubble diffusion member 330 in the form of a cylinder with a closed front, and a predetermined angle is provided on the outer periphery of the front part. A plurality of diffusion holes 334 are formed at intervals.

In addition, in the bubble diffusion member 330 in which the diffusion hole 334 is located, a disk-shaped diffusion plate 336 protruding a predetermined length from the front surface is formed.

Accordingly, the microbubbles that have passed through several components spread in a radial direction while colliding with the diffusion plate 336 , and then pass through the diffusion hole 334 again to be discharged to the outside of the bubble diffusion member 330 .

Accordingly, in order to increase the diffusion efficiency of the diffusion plate 336 , a surface-processed portion 336a in which a front portion of the diffusion plate 336 is surface-machined at a predetermined angle is formed on the diffusion plate 336 .

On the other hand, the microbubbles introduced into the interior of the body 310 through the diffusion holes 334 of the bubble diffusion member 330 are discharged through the discharge holes 322 of the cover 320 mounted on the front of the body 310. It is transferred to the ejection hose 272 outside the case 201.

In addition, a screw thread 320a is formed on the outer circumferential surface of the cover 320 so that the cover 320 is coupled to the case 201 and the jet hose 272 .

And the cap 360 is assembled in the housing 314. In this way, the user can hold the knob 338 and tighten or loosen the bubble diffusion member 330 during assembly and disassembly of the parts.

The cap 360 accommodated in the housing 314 accommodates a pressure plate 370 that converts the introduced gas-liquid into fine bubbles of finer particles or has a structure in which a nozzle hole 362 is formed in itself. .

In addition, a plurality of pressure holes 372 are formed through the pressure plate, and a seal ring 380 for maintaining airtightness around the pressure plate 370 is mounted.

And the number of nozzle holes 362 for making the fluid passing through the pressure holes 372 of the pressure plate 370 into finer particles is formed in a number greater than the number of the pressure holes 372 of the pressure plate 370 described above, the cap The diameter of the nozzle hole 362 on the 360 is formed smaller than the diameter of the pressure hole 372 on the pressure plate 370 , and the spacing between the nozzle holes 362 is also narrower than the spacing of the pressure holes 372 . do.

Accordingly, the nozzle hole 362 makes the size of the bubbles passing through the pressure hole 372 become smaller.

Meanwhile, the nozzle hole 362 may have a rectangular shape or a circular shape.

A female screw 354 and a male screw 364 for screw assembly are respectively formed on the inner and outer circumferences of the housing 314 and the cap 360 .

In addition, a tool groove 366 is formed on the front surface of the cap 360 so that a tool can be used when assembling or disassembling the cap 360 with respect to the housing.

In the microbubble ejection device 300 configured as described above, the gas-liquid in the bubble state introduced through the gas-liquid suction pipe connected to the rear of the main body 310 passes through the pressure hole 372 formed in the pressure plate 370, and the impact energy At the same time, the flow rate increases.

Therefore, the particles of the bubbles after passing through the pressure hole 372 are smaller than the particles of the bubbles when passing through the gas-liquid suction pipe 230 .

In addition, the fluid passing through the pressure hole 372 of the pressure plate 370 passes through the nozzle hole 362 of the cap 360 installed on the front side thereof, receives impact energy and increases the flow rate.

Accordingly, the particles of the bubble when passing through the pressure hole 372 of the pressure plate 370 are split into smaller particles and separated to generate very fine microbubbles.

And the microbubbles generated while passing through the nozzle hole 362 collide with the diffusion plate 336 installed inside the bubble diffusion member 330 and spread in the radial direction, and then through the diffusion hole 334 of the cover 320 will flow backwards.

Thereafter, the microbubbles introduced to the rear of the cover 320 are transferred to the ejection hose 272 through a plurality of discharge holes 322 formed in the cover 320 .

In the microbubble generating device 200 for plant cultivation according to the present invention configured as described above, water is sucked through the internal suction pipe 215 in the case 201 by the circulation pump 220 to the gas-liquid mixing pipe 230 . The water sucked in and sucked into the gas-liquid mixing pipe 230 is mixed with the air sucked in through the air suction pipe 232, and then through the circulation pump 220 and the gas-liquid pipe 250 through the pressure tank 240. is transferred to

And, in particular, the gas-liquid transferred to the pressure tank 240 collides with the collision plate 246 installed at an inclined angle in the pressure tank 240 inside 241a.

The gas-liquid collided in this way has high energy, so high energy is absorbed and falls through the gas-liquid discharge hole 246a of the collision plate 246 .

In addition, the dropped gas-liquid is changed to a high-energy gas-liquid as it falls on the bottom of the body 241 and receives an impact once more.

As described above, the gas-liquid discharged at high impact and high speed absorbs high energy, and microbubbles are generated through the microbubble ejection device 300, and the ejection hose 272 and ejection head 274 outside the case 201 ) is ejected to the outside.

As described above, the water for plant cultivation of microbubbles containing high energy plays a role in facilitating the supply of oxygen in the underground part and promoting the growth of various agricultural products. Promotes the growth of the above-ground part.

And the microbubble generating device 200 for plant cultivation according to the present invention improves portability by mounting most parts of the device in the case 201, so that the operator can use the device easily and can be used for various types of plants. can

On the other hand, reference number 202 not described in FIG. 2 is a handle, reference number 203 is a pressure gauge used in the apparatus 200 for generating microbubbles for plant cultivation according to the present invention, and reference number 204 is a microbubble for plant cultivation according to the present invention It is a power switch of the bubble generating device 200, c.

As described above, the present invention has been described with reference to one embodiment shown in the drawings, but this is merely exemplary, and various modifications and equivalent embodiments are possible therefrom by those skilled in the art. will understand

Accordingly, the true protection scope of the present invention should be defined only by the appended claims.

200: micro-bubble generator
201: case
212: suction head
214: external suction hose
215: internal suction pipe
220: circulation pump
230: gas-liquid mixing pipe
240: pressure tank
241: body
245: air vent
246: collision plate
246a: gas-liquid discharge hole
250: gas-liquid tube
260: priming bucket
272: ejection hose
274: ejection head
275: gas-liquid discharge pipe
300: microbubble ejection device
310: body
312: pipe connection
314: housing
320: cover
322: exhaust hole
370: pressure plate
380: seal ring

Claims (8)

case;
a suction head installed outside the case and provided to suck water;
an external suction hose connected to the suction head so that water can be transferred into the case;
an internal suction pipe installed inside the case and connected to the external suction hose;
a circulation pump for forcibly sucking water through the internal suction pipe;
a pressure tank for discharging the gas-liquid transferred through the circulation pump to the outside by applying a constant pressure;
a gas-liquid pipe connected to the circulation pump and an upper part of the pressure tank so that the gas-liquid is transferred to the pressure tank;
a gas-liquid discharge pipe connected to one side of the lower side of the pressure tank and installed inside the case to transport the gas-liquid discharged from the pressure tank;
a micro-bubble ejection device installed at the end of the gas-liquid discharge pipe and installed inside the case to generate micro-bubbles from the gas-liquid introduced through the gas-liquid discharge pipe;
a jet hose connected to the microbubble jetting device, installed connected to the outside of the case, and jetting microbubbles to the outside of the case; and
a jet head installed connected to the end of the jet hose so that the microbubbles blown out through the jet hose are directly used as water for plant cultivation;
A device for generating microbubbles for plant cultivation, characterized in that it comprises a. According to claim 1,
The pressure tank is
body; and
A collision plate installed on one side of the inside of the body and configured to cause a collision while the gas-liquid falls into the supplied pressure tank; includes;
A device for generating microbubbles for plant cultivation, characterized in that a plurality of gas-liquid discharge holes are formed in the collision plate so that the dropped gas-liquid falls back to the lower portion of the collision plate. According to claim 1,
The collision plate is a microbubble generating device for plant cultivation, characterized in that it is installed to be inclined at a predetermined angle inside the body. 4. The method of claim 3,
The collision plate is installed at an angle of 45° to 60°, a device for generating microbubbles for plant cultivation. According to claim 1,
The gas-liquid discharge hole is a micro-bubble generating device for plant cultivation, characterized in that formed in a circular shape. According to claim 1,
The microbubble generating device for plant cultivation, characterized in that the upper portion of the body is provided with an air vent for automatically discharging air when the pressure exceeds a certain level inside the body to maintain a constant pressure. According to claim 1,
The microbubble ejection device,
main body;
a pipe connection part formed at the rear of the main body and connected to the gas-liquid discharge pipe;
a cover installed in front of the main body and having a plurality of outlet holes to eject microbubbles generated in the main body to the external ejection hose, and a hose coupling portion coupled to the external ejection hose;
a cylindrical member installed in the body to one side of the pipe connection part;
a housing installed in the cylindrical member; and
and a bubble diffusion member installed in front of the housing to diffuse microbubbles and formed with a diffusion plate protruding a certain length to the rear. 8. The method of claim 7,
A device for generating microbubbles for plant cultivation, characterized in that a surface-processed part is formed at a predetermined angle in front of the diffusion plate.

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