KR102191010B1 - The belt drip for emitting pipe - Google Patents

Abstract

In the process of discharging water through the discharge hole of the water conduit through a band drip fused to the inner surface of the water conduit, it is sprayed in the direction where water is supplied and flows through the discharge hole instead of flowing through the water conduit. A decompression protrusion located at the end of the decompression furnace formed in the drip portion of the strap so that it can be dropped on one side of the strip is formed extending from the decompression protrusion in the longitudinal direction of the discharge space at a predetermined distance from the inner side of the strap body. A guide formed by an induction guide; A conversion guide formed at the end of the guide path to change the direction of the water guided from the guide path toward the discharge space; And at least one connection path formed between the induction guide or the induction guide and the conversion guide so as to be connected to the discharge space.
Accordingly, it has the effect of maximizing the cultivation efficiency of crops while minimizing the supply of water.

Description

The belt drip for emitting pipe

The present invention relates to a strip drip for a water conduit, and more particularly, in the process of discharging water through a discharge hole of a water conduit through a strip drip fused to the inner surface of a water conduit, the water conduit is sprayed in the direction where water is supplied. It is related to a strip drip for water conduit that allows it to fall directly under one side of the water conduit while overflowing from the discharge hole rather than through the flow.

In general, water conduits are arranged side by side at regular intervals to supply water appropriately to crops planted on a wide site, and discharge holes are formed at regular intervals to supply water to crops planted locations.

In addition, the water from the water conduit is discharged through the discharge hole by the pressure of a pump, etc., and in the process of discharging the water through the discharge hole formed at a location near or far from the pump, a certain amount of water is discharged in the discharge hole. A drip is provided to reduce the pressure and supply it.

The drip is divided into a single drip that is fused to the bottom of the discharge hole and a band drip that has a relatively long length.

In the present application, an example applied to a band drip among dripping will be described.

As shown in FIG. 5, the conventional general strip drip 100 is a band that is fused to the inner surface of the water conduit so as to be positioned between the discharge hole 202 and the discharge hole 202 formed at regular intervals in the water conduit 200. Each drip portion 120 is formed on the body 110.

The drip unit 120 includes an inlet passage 122 through which water flows between the plurality of protrusions 122A, and a plurality of decompression protrusions that are formed to be shifted one by one to reduce the pressure of the water introduced through the inlet passage 122. The decompression furnace 124 formed between (124A), the discharge space 125 located below the discharge hole 202 at the end of the decompression furnace 124 to collect water, and the discharge space 125 It has a technical configuration including a protruding bar 126 protruding in the longitudinal direction on the upper and lower surfaces.

The protruding bar 126 is used to easily check the location when drilling the discharge hole 202 in the water conduit 200.

As described above, in the prior art related to the strip drip, as published in Korean Patent Publication No. 10-0528725 (hereinafter referred to as'prior art document 1'), a gap is provided inside the decompression hose (corresponding to the'water conduit'). Each unit is configured to be continuously and repeatedly formed on a single body in the form of a strip by forming a unit of a plurality of individually attached decompression pieces, regardless of changes in the pressure or inflow of water flowing into the inside of the decompression hose. A technique such as a decompression piece for a decompression hose has been proposed so that the pressure of water discharged through the water inlet, the decompression protrusion and the outlet, and the ejection hole formed in the decompression hose on the outlet can always be kept constant.

In addition, as published in Korean Patent Publication No. 10-1218325 (hereinafter referred to as'prior technical document 2'), when the hydraulic pressure of water flowing inside the pipe (corresponding to the'water conduit') is changed, elastic deformation in response thereto. A technology such as a water conduit equipped with a drip capable of maintaining a constant flow rate of the final discharged water even when the hydraulic pressure fluctuates within a certain range has also been proposed.

In addition, as published in Korean Patent Application Publication No. 10-2018-0007489 (hereinafter referred to as'prior technical document 3'), a technology such as drip for water conduit with excellent decompression effect of fluid by having a complex flow path has also been proposed. have.

Korean Registered Patent Publication No. 10-0528725 Korean Patent Publication No. 10-1218325 Korean Patent Application Publication No. 10-2018-0007489

However, the conventional conventional strip drip as well as the strip drip published in Prior Art Documents 1 to 3, as shown in Figure 6, the water discharged from the discharge hole of the water conduit does not fall directly below the discharge hole, but to other discharge holes. As it flows along the outer circumferential surface of the water conduit, it has a disadvantage that water supply to crops located in the lower part of the discharge hole is not smoothly performed.

In other words, the space between the discharge space of the strip drip and the inner surface of the water conduit is quite narrow, as well as the water collected in the discharge space also has a predetermined pressure, so that the water in the discharge space is sprayed in the direction of flow when it leaves the discharge hole. As it is discharged, it has a problem that it flows along the outer surface of the water conduit.

A specific technical solution of the present invention for solving the above-described problems in the related art is spraying in the direction in which water is supplied in the process of discharging water through the discharge hole of the water conduit through a band drip fused to the inner surface of the water conduit. It is to provide a strip drip for water conduit that allows it to fall directly under one side of the water conduit while overflowing from the discharge hole instead of flowing through the water conduit.

Another specific technical solution of the present invention is to facilitate the discharge of water discharged through the discharge hole in the form of droplets.

The specific technical solution of the present invention for solving the above technical problems is to be located between the discharge hole and the discharge hole formed at regular intervals in the water conduit, so that the water through a plurality of protrusions is fused to the inner surface of the water conduit. A decompression path formed between an inflow path into which is introduced and a plurality of decompression protrusions that are formed to be shifted one by one so as to reduce the pressure of the water introduced through the inflow path, and located below the discharge hole at the end of the decompression path. A band drip including a discharge space where water is collected, and each drip part including a protruding bar protruding in a longitudinal direction on an upper surface and a bottom surface of the discharge space, and the band body in the decompression protrusion located at the end of the decompression furnace A guide path formed by an induction guide extending in the longitudinal direction of the discharge space from the decompression protrusion at a predetermined distance from the inner surface of the device; A conversion guide formed at the end of the guide path to change the direction of the water guided from the guide path toward the discharge space; And at least one connection path formed between the guide guide or the guide guide and the conversion guide to be connected to the discharge space.

The width of the guide furnace is formed to be wider than the width of the end of the decompression furnace so that the pressure of the water decompressed in the decompression furnace is further reduced.

The conversion guide is formed to be inclined toward the guideway.

The end of the conversion guide is formed to protrude more than the guide guide toward the discharge space.

The inner periphery of the discharge hole may further include that formed so as not to contact or overlap the end of the conversion guide.

In the present invention, in the process of discharging water through the discharge hole of the water conduit through a band drip fused to the inner surface of the water conduit, while spraying in the direction of supplying water, it does not flow through the water conduit, but overflows from the discharge hole. It has the effect of maximizing the cultivation efficiency of crops while minimizing the supply of water by allowing the water to fall directly under the water pipe.

In addition, by allowing the water discharged through the discharge hole to be smoothly discharged in the form of droplets, the efficiency of supplying water to crops can also be maximized.

1 is a perspective view for explaining the present invention,
Figure 2 is a plan view according to Figure 1,
3 is a flat cross-sectional view for explaining the state of use of the present invention,
Figure 4 is a photograph of the water discharged while the present invention is fused to a water conduit;
5 is a plan view for explaining a conventional general strip drip,
6 is a photograph taken of water discharge while the band drip of FIG. 5 is fused to a water conduit.

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

1 is a perspective view for explaining the present invention, Figure 2 is a plan view according to Figure 1, Figure 3 is a flat cross-sectional view for explaining the use state of the present invention, Figure 4 is a state in which the present invention is fused to a water conduit This is a picture of the water being discharged from.

As shown, the conventional strip drip 100 is fused to the inner surface of the water conduit 200 so as to be located between the discharge hole 202 and the discharge hole 202 formed at a predetermined interval in the water conduit 200. A plurality of decompression protrusions formed to be shifted one by one to depressurize the pressure of the water flowing through the plurality of protrusions 122A into the belt body 110 and the pressure of the water introduced through the inlet 122 The decompression furnace 124 formed between (124A), the discharge space 125 located below the discharge hole 202 at the end of the decompression furnace 124 to collect water, and the discharge space 125 Each of the drip portions 120 including protruding bars 126 protruding in the longitudinal direction on the upper and lower surfaces thereof are included.

Here, the biggest technical issue in the strip drip 100 is to make the water discharged from the discharge hole 202 of the water conduit 200 fall in a form of droplets directly below the location.

However, in the case of general strip drip, as described in the technology behind the invention, the space between the discharge space of the strip drip and the inner surface of the water conduit is quite narrow, and the water collected in the discharge space also has a predetermined pressure. Accordingly, there is a problem in that the water in the discharge space flows along the outer surface of the water conduit as it is discharged as if it is sprayed in the direction in which the water flows when it leaves the discharge hole.

As a result, there has been a problem in that water for cropping cannot be supplied smoothly to crops located in the lower part of the discharge hole. Accordingly, a large amount of unnecessary water is used, and the cultivation efficiency of crops is also significantly lowered.

In the present invention, in the process of discharging water through the discharge hole of the water conduit through a band drip fused to the inner surface of the water conduit, while spraying in the direction of supplying water, it does not flow through the water conduit, but overflows from the discharge hole. It is to make it possible to fall directly underneath while riding on one side of the water conduit.

The strip drip 100 according to the present invention is a discharge space from the decompression protrusion 124A at a predetermined distance from the inner surface of the strip body 110 in the decompression protrusion 124A located at the end of the decompression furnace 124 A guide path 10 formed by a guide guide 12 extending in the longitudinal direction of 125; A conversion guide 20 formed at the end of the guide path 10 to change the direction of the water guided from the guide path 10 toward the discharge space 125; And at least one connection path 30 formed between the guide guide 12 or the guide guide 12 and the conversion guide 20 so as to be connected to the discharge space 125.

At this time, the width (W) of the guide path (10) is formed to be wider than the end width (w) of the decompression path (124) so that the pressure of the water decompressed in the pressure reduction path (124) is further reduced.

In other words, the present invention prevents the water from flowing along the outer surface of the water conduit by being sprayed from the point when it leaves the discharge hole due to constant pressure generated after the water passing through the decompression furnace is directly collected into the discharge space, and the discharge hole is It is made to fall in the form of droplets directly below the formed water conduit.

That is, the water passing through the decompression path flows into the guide path formed by the guide guide formed at a predetermined distance from the inner surface of the belt body. At this time, as the width of the guide furnace is formed to be wider than the width of the end of the decompression furnace, the pressure of the water decompressed in the decompression furnace is further reduced.

In this way, the water passing through the guide path is changed in a direction orthogonal to the water flow direction by the conversion guide, and flows into the discharge space through the connection path and is collected.

As a result, the water collected in the discharge space is not sprayed in the direction in which the water flows at the time it is discharged from the discharge hole, but flows directly under the side of the water conduit on one side of the discharge hole and falls in the form of drops. One of the above refers to the first flow of water.

In other words, the water collected in the discharge space has a lower pressure than the decompression furnace, and the water is not discharged in the direction where the water is supplied, but is changed in a direction perpendicular to the water supply, and then collected into the discharge space and then discharged. By being discharged through the outlet, the water is discharged not in a sprayed form, but in a form overflowing from the discharge hole, and flows directly under the side of the water conduit on one side of the discharge hole and falls in the form of droplets.

Accordingly, it is possible to smoothly supply water to the crops planted in the lower part of the discharge hole.

Accordingly, the present invention does not have a complicated technical configuration, but by a simple structure, that is, by further reducing the pressure of the water and at the same time converting the flow of water in a direction orthogonal to the direction in which the water is supplied, the largest in a band drip. It solves the technical problem of allowing the water discharged from the discharge hole of the water conduit, which is the technical key, to flow directly below the water pipe and smoothly fall in the form of droplets.

As a result, crop growth as well as harvesting efficiency can be further maximized.

In addition, as the water supply is accurately supplied to the crops, it is supplied in an optimal amount without unnecessary amounts, and there is also a condition to minimize the use of water.

On the other hand, the conversion guide 20 is formed to be inclined toward the guide path 10, so that the water guided from the guide further reduces the impact upon contact with the conversion guide, and then the direction to the discharge space is smoothly changed. Make it possible. That is, when the water is in contact with the inclined conversion guide, the impact is reduced by the inclined surface inclined in the direction opposite to the direction in which the water is guided, and the direction can be smoothly changed toward the discharge space while riding the inclined surface.

In addition, the end of the conversion guide 20 is formed to protrude more than the induction guide 12 toward the discharge space 125, so that the water changed direction after contact with the conversion guide can be more smoothly guided to the discharge space. It is desirable to be able to. At this time, when the end of the conversion guide is shorter than the position of the guide guide, it is preferable to form longer than the location where the guide guide is located because the direction of the water guided to the discharge space is not smoothly changed.

In addition, the inner periphery of the discharge hole 202 further includes that formed not to be in contact with or overlap with the end of the conversion guide (20).

In other words, if the inner circumference of the discharge hole is formed far from the end of the conversion guide, water discharged from the discharge hole can be sprayed in the opposite direction to which water is supplied, and when it overlaps the conversion guide, water is supplied as in the prior art. Since it can be sprayed in the direction in which the discharge hole is formed, it is preferable that the inner periphery of the discharge hole is formed so as not to contact or overlap the conversion guide.

10: as a guide 12: guided guide
20: conversion guide 30: connecting road
100: strip drip
110: belt body 120: drip part
122: inflow path 122A: protrusion
124: decompression furnace 124A: decompression protrusion
125: discharge space 126: protruding bar
200: water conduit 202: discharge hole

Claims (5)

An inlet passage through which water flows through a plurality of protrusions to the belt body fused to the inner surface of the water conduit so as to be located between the discharge hole and the discharge hole formed at regular intervals in the water conduit, and the pressure of the water introduced through the inlet passage A decompression furnace formed between a plurality of decompression protrusions that are formed to be shifted one by one to decompress the pressure, a discharge space in which water is collected by being located under the discharge hole at the end of the decompression furnace, and a length on the upper and lower surfaces of the discharge space A strip drip including each drip portion including a protruding bar protruding in a direction,
A guide path formed by an induction guide extending in the longitudinal direction of the discharge space from the decompression protrusion at a predetermined distance from the decompression protrusion on the decompression protrusion located at the end of the decompression furnace;
At the end of the guideway, the water guided from the guideway is diverted toward the discharge space, and the water is discharged in a form overflowing from the discharge hole rather than spraying, and the side of the water conduit on one side of the discharge hole is A conversion guide formed to flow directly under the ride and fall in the form of drops; And
At least one connection path formed between the guide guide or the guide guide and the conversion guide to be connected to the discharge space; includes,
The width of the guide furnace is formed to be wider than the width of the end of the decompression furnace so that the pressure of the water decompressed in the decompression furnace is further reduced,
The conversion guide is a strip drip for water conduit that is formed to be inclined toward the guideway so that the water guided from the guide can further reduce the impact when the water is in contact with the conversion guide, and then change the direction toward the discharge space smoothly. delete delete The method of claim 1,
A strip drip for water conduit formed at the end of the conversion guide to protrude more than the guide guide toward the discharge space. The method of claim 1 or 4,
The inner circumference of the discharge hole is a band drip for water conduit, further comprising formed so as not to contact or overlap the end of the conversion guide.

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