KR101981495B1 - Fog drip - Google Patents

Abstract

A plurality of inflow holes for discharging water from the discharge holes of the water pipe by being swirled in the form of vortex while being rotated after the water is fused to the inner side of the water pipe to discharge the water, A cover member having a cone-shaped protrusion formed on a bottom surface of the opposite side where the inflow hole is formed; And a guide chuck having a predetermined height for allowing water to flow therethrough in contact with a bottom surface of the cover member is formed on an upper surface of the guide chuck, , And a discharge space formed with a discharge hole in which the lower end of the reduced pressure passage is connected to the inner side of the guiding portion and the decompressed water is rotated to insert the lower portion of the cone-shaped projection into a vortex form to be discharged in a spray form And a dripping member which is made of a plastic material.
Accordingly, it is possible to maximize the supply efficiency of the water, as well as maximize the supply area of the water, thereby maximizing the water supply efficiency to the crop and the soil.

Description

Fog drip {Fog drip}

More particularly, the present invention relates to a fogging dripping apparatus, and more particularly, to a fogging dripping apparatus which is fused to an inner surface of a water supply pipe, discharges the water, decompresses the water, winds the water in a vortex form, (Sprayed) in the form of a fog drip.

Generally, a drinking water pipe used for cultivation of crops is a pipe arranged at regular intervals so as to supply appropriate water to crops planted on a wide area. Each of the water pipes is provided with a plurality of discharge holes do.

In addition, in the problem that the water having increased pressure by the pump is discharged through each discharge hole of the water pipe, in order to supply a certain amount of water to both the discharge hole disposed close to the pump and the distant position, A drip for supplying the pressure under reduced pressure is provided.

Such drips supply the water to the crop at a constant pressure. In order to supply water at a constant flow rate, it is common to supply the water after the pressure is increased.

Prior art related to the drip provided in the discharge hole of the water supply pipe as described above is disclosed in Korean Utility Model Registration No. 20-0449454 and Korean Patent Registration No. 10-0748604 (hereinafter, referred to as 'Prior Art Document 1' Quot;).

However, the drips disclosed in the above-mentioned prior art document 1 have a disadvantage that they are limited only to a portion where the supply of water drops when the droplets used for the drip are dropped and supplied while discharging the water after decompressing the water.

In order to solve such a problem, conventionally, as disclosed in Korean Utility Model Registration No. 20-0478546 (hereinafter referred to as "Prior Art Document 3"), a rotation force formed at a position oriented toward a point spaced from the center of the rotation space There has been proposed a technique such as a rotary spraying type fountain hose for plant cultivation in which a rotating force is generated in the water flowing into the rotary space through the feed path and is ejected through the ejection port.

Also, as disclosed in Korean Utility Model Registration No. 20-0478547 (hereinafter referred to as "Prior Art Document 4"), there is provided an irrigation control means for controlling the ejection characteristics of water to be ejected, And the rotation generating unit generates a rotating force in the water flowing into the rotating space through a rotating force applying path formed at a position oriented at a position separated from the center of the rotating space, Techniques such as fountain hoses for plant cultivation including irrigation control means have also been proposed.

Korean Utility Model Registration No. 20-0449454 Korean Patent Registration No. 10-0748604 Korean Utility Model Registration No. 20-0478546 Korean Utility Model Registration No. 20-0478547

However, the prior art documents 3 to 4 have a disadvantage in that the technical structure for applying the rotational force to the water is complicated, and the efficiency of decompression of the water is low, and the discharge of water from the discharge hole located at a distance from the discharge hole near the pump is uniform .

In order to solve the above-described problems, the present invention has been made to solve the above-mentioned problems in the prior art, and it is an object of the present invention to provide a water- To be discharged in the form of spray from the discharge hole of the fog drip.

Another specific object of the present invention is to enable smooth discharge of the water into the spray form even if the center of discharge of the water and the center of the discharge hole of the water supply pipe do not exactly coincide with each other.

Another specific object of the present invention is to further accelerate the discharge of the water into the vortex form.

According to an aspect of the present invention, there is provided a method of manufacturing an inflow hole, the method comprising: forming a plurality of inflow holes through which upper and lower surfaces are closed, A cover member having a cone-shaped protrusion formed on the lower surface of the opposite side; And a guide protrusion having a predetermined height for allowing water to flow therethrough in contact with a bottom surface of the cover member is formed on an upper surface of the guide protrusion, Wherein the inflow space into which the water introduced through the inflow hole flows into the inflow space is formed in a zigzag shape between the plurality of protrusions protruding one by one from the opposing surfaces of the guide tabs at the end of the inflow space, And a discharge space formed with a discharge hole in which a lower portion of the cone-shaped projection is inserted and is wound in a vortex form to be discharged in a spray form is provided, Member.

An insertion groove corresponding to a lower portion of the cone-shaped projection on the bottom surface of the discharge space, and the discharge hole formed at the center of the insertion groove.

The discharge hole is formed to have a wider diameter than the lower end of the cone-shaped projection.

The discharge hole is formed wider and wider toward the bottom side of the drip member.

The protrusion of the cone shape may further include at least one spiral guide groove.

In the present invention, the water is fused to the inner surface of the water supply pipe and discharged in the process of discharging the water, and then the water flows in the form of a vortex while being rotated while being decompressed to be discharged in the form of spray from the discharge pipe of the water supply pipe. The efficiency of supply of water to the crops and the soil can be maximized by maximizing the supply area of the water.

In addition, even if the center of discharge of the water and the center of the discharge hole of the water supply pipe are not precisely matched, discharge to the spray form can be performed smoothly, so that work for forming discharge holes to the water supply pipe can be made more convenient Also has an effect.

In addition, by allowing the water to be further accelerated to be vortexed in a vortex form, the supply area of the water to be discharged in the form of spray can be further increased, and the water supply efficiency of the water can be further increased It also has an effect.

1 is an exploded perspective view for explaining the present invention,
Figure 2 is a cross-sectional view of the combined state according to Figure 1,
3 is a plan view according to FIG. 2,
4 is a bottom perspective view for explaining the use state of the present invention,
5 is an exploded perspective view for explaining another embodiment of the present invention.

Hereinafter, preferred embodiments of the present invention will be described in more detail with reference to the accompanying drawings. The present invention is not limited to the embodiments.

1 is an exploded perspective view for explaining the present invention, FIG. 2 is a cross-sectional view of the combined state according to FIG. 1, FIG. 3 is a plan sectional view according to FIG. 2, It is a bottom perspective view.

As shown in the drawing, a typical water supply pipe 100 is arranged at regular intervals in order to supply appropriate water to the crops planted on a wide area, and the water supply pipe 100 is provided with a plurality of discharge holes 102 are formed.

Further, in each of the above-mentioned exhaust holes, a drip that supplies water with increased pressure by a pump or the like to the discharge holes by reducing the pressure of the water to supply a certain amount of water to both of the discharge holes disposed near or far from the pump .

Such conventional drips have drawbacks in that water is supplied to the crops by discharging the water in the form of droplets, which are usually in the form of droplets, which is not efficient in supplying water.

The present invention relates to a water purifier for a water purifier that fuses to an inner surface of a water supply pipe and discharges the water in a process of discharging the water from a discharge pipe of the water pipe, .

The fog drip (1) according to the present invention is formed such that its top and sides are closed and its bottom is opened, and a plurality of inflow holes (12) through which water flows vertically through one side of the top face are formed, And a cover member 10 in which a cone-shaped protrusion 14 is formed on the lower side of the bottom surface of the side opposite to the front surface. The cover member is usually in the form of a rectangular box.

In addition, the cover member 10 is inserted into the opened lower portion of the cover member 10, and is fixed by a conventional interference fit method. The cover member 10 has a predetermined height so as to be in contact with the bottom surface of the cover member 10, An inlet space 23 through which the water introduced through the inlet hole 12 flows into the guide jaw portion 22 at a position corresponding to the inlet hole 12 on one side of the guide jaw portion 22, A decompression furnace (24) formed in a staggered manner between a plurality of protrusions (24A) protruding one by one from one another on opposite surfaces of the guide shoulder portion (22) at the end of the space (23) And the lower portion of the cone-shaped protrusion 14 is inserted and is wound in the form of a vortex to form a discharge hole 26A through which the discharge hole 26A is discharged in the form of a spray, The space 26 is provided Include; lip member (20).

The insertion hole 26B is formed in the bottom surface of the discharge space 26 in correspondence with the lower portion of the cone shaped protrusion 14 and the discharge hole 26A is formed in the center of the insertion groove 26B . At this time, a gap is formed between the protrusion of the cone shape and the insertion groove so that the water flows in the form of a vortex flow.

According to the above configuration, the water introduced through the inflow hole of the cover member flows into the inflow space formed at one side of the guide protrusion of the drip member.

Then, the water under a reduced pressure in the inflow space through the decompression furnace flows into the discharge space connected to the end of the decompression furnace and the inner side of the guide protrusion, and simultaneously, it is rotated.

In this way, the water to be rotated is swirled in the form of a vortex on the cone-shaped protrusion of the cover member having the lower portion inserted into the insertion groove formed in the bottom surface of the discharge space, and is discharged through the discharge hole formed in the water supply pipe It is released in spray form.

In other words, as the water is rotated in a vortex shape on the outer surface of the cone-shaped projection, the rotational force is increased, and the water is discharged in the form of a vortex also in the discharge hole. At the same time, Is not discharged in droplets in the form of droplets but is discharged in the form of spray as if it spreads in the form of mist. Particularly, as the water is discharged from the narrow gap between the cone-shaped projection and the insertion groove to the large space of the atmosphere through the discharge hole, that is, the water is discharged in the form of spray by the Bernoulli principle.

As a result, the water is discharged in a spray form, thereby maximizing the supply area of the water, thereby providing a condition that the supply of the crops can be uniformly distributed to the crops as well as the soil where the crops are planted. This also has the advantage of naturally maximizing the cultivation efficiency of crops.

And the discharge hole 26A is formed to have a wider diameter than the lower end of the cone-shaped projection 14. [ In other words, when the discharge hole is narrower than the lower end of the cone-shaped projection, the discharging hole is wider than the cone-shaped lower projection So that water can be smoothly discharged by being wound in the form of a vortex in a cone-shaped projection.

Further, the discharge hole 26A is formed to be wider and wider toward the bottom side of the drip member 20.

This is because even if the discharge hole 102 formed in the water supply pipe 100 is not exactly aligned with the center of the discharge hole 26A and there is a slight difference, the water is already vortexed and discharged in a vortex form on the cone- As the requirements are met, even if there is a slight deviation from the center of the discharge hole, the water has a condition in which the discharge can be smoothly performed in the sprayed form.

Therefore, it is not necessary to precisely match the discharge hole formed in the water supply pipe with the discharge hole, thereby making it possible to further enhance the convenience of the operation.

Therefore, in the present invention, water is discharged in a vortex form in a vortex form along with rotation in the process of supplying water, so that the water discharged through the discharge hole of the water pipe is not discharged as droplets, So that the supply area can be maximized.

This has the advantage of maximizing the efficiency of cultivation by supplying water evenly to crops as well as to soil for cultivation of crops.

5 is an exploded perspective view for explaining another embodiment of the present invention.

As shown in the drawings, in the above-described configuration, a technical configuration capable of further increasing the amount of water vortexed and discharged is also provided.

The cone-shaped protrusion 14 may further include at least one spiral guide groove 14A.

That is, when the water is rotated in a vortex shape on the outer surface of the cone-shaped protrusion together with the rotation, the guide groove can be rotated more quickly to increase the rotational force.

This, in turn, results in a condition in which the entrainment in the vortex shape increases the rotational force so that it can be spread over a higher area when sprayed as mist through the exhaust port of the solvent conduit.

Further, when the guide groove is formed in the protrusion of the cone shape, the water can be smoothly rotated in the vortex shape even if the insertion groove is in contact with the protrusion of the cone shape without any gap.

1: fog drip
10: cover member 12: inflow hole
14: projection in cone shape 14A: guide groove
20: drip member 22: guide jaw
23: inflow space 24: reduced pressure furnace
24A: projection 26: discharge space
26A: Release hole 26B: Insert groove
100: Water supply pipe 102: Exhaust hole

Claims (5)

A plurality of inlet holes through which the water flows vertically through one side of the upper surface are formed, and cone-shaped protrusions are formed on the lower side of the opposite side where the inlet holes are formed. ; And
A guide protrusion having a predetermined height for allowing water to flow therethrough in contact with the bottom surface of the cover member is formed on the upper surface of the guide member, The inlet space through which the water flowing in through the inlet hole is introduced is formed in a zigzag shape between a plurality of protrusions protruding one by one on opposite faces of the guide protrusions on the end of the inlet space, And a discharge space formed with a discharge hole formed in the shape of a vortex in which the lower portion of the cone-shaped projection is inserted and is wound in a vortex shape while the decompressed water is rotated to connect the end of the reduced pressure passage to the inner side of the guide- ; ≪ / RTI >
An insertion groove formed in the bottom surface of the discharge space in a shape corresponding to a lower portion of the cone-shaped projection, and the discharge hole formed at the center of the insertion groove,
The discharge hole is formed to have a wider diameter than the cone bottom end of the cone shape,
Wherein the cone-shaped protrusion further includes at least one spiral guide groove formed on the outer surface of the cone-shaped protrusion so as to increase the rotational force of the water in a vortex shape. delete delete The method according to claim 1,
Wherein the discharge hole is formed to be wider and wider toward the bottom side of the drip member. delete

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