KR200376067Y1 - Drip irrigation system for agricultural cultivation - Google Patents

Abstract

The present invention relates to a drop irrigation structure for crop cultivation, and more particularly, a dropper prepared to cope with the clogging phenomenon of micropores, which supplies a proper amount over a large area with a small amount of water effectively and evenly, and discharges water. It has a cylindrical shape to be crimped and embedded in the inner diameter of the water hose, and the sealing part protrudes in the longitudinal end, and the outer circumferential surface receives a part of the water flowing in the hose to receive hydraulic pressure through many bending paths. A pressure reducing part is formed to sufficiently reduce the pressure, and the pressure-reduced water is discharged to the outside through at least two or more micropores installed in the hose, and the fine curved part of the pressure reducing part is oxidized and corroded by iron ions or the like contained in the water. In order to prevent clogging, it is manufactured by mixing tourmaline in the dropper material. All.

Description

DRIP IRRIGATION SYSTEM FOR AGRICULTURAL CULTIVATION}

The present invention relates to a drop irrigation structure for cultivating crops, and more specifically, the dropper is cylindrical in shape so as to be compressed and embedded in an inner diameter of a hose for watering (HOSE), and a sealing part is protruded in the longitudinal end. On the outer circumferential surface, a pressure reducing part is formed to receive a part of the water flowing in the hose to sufficiently reduce the water pressure through many curved paths, and the pressure-reduced water as described above is dripped out through at least two micropores installed in the hose. It was drained.

The water needed during the cultivation of crops needs to be adequately supplied, repetitive and continuous, and when these conditions are met, good quality crops are obtained.

However, if only depend on precipitation in crop cultivation, the crop is dried or degraded in dry season, so many methods have been created to supply water randomly without depending on precipitation.

In particular, when growing crops in a plastic house, arbitrary water supply is essential, but it takes a lot of effort and money to draw water continuously and repeatedly in time.

As an effective way to give water to crops more conveniently, the so-called drip method of supplying water dropwise to the roots of crops continuously and repeatedly has been widely used.

For example, the Republic of Korea Utility Model Publication No. 1990-0011266 is to install a dropper at a predetermined equal intervals in the hose for watering, the dropper is installed outside the hose.

However, while the above-described device in which the dropper is installed outside the hose is suitable for installing the hose on the crop and allowing water to fall into the crop, the buried space in addition to the hose occurs when buried underground. It also interferes with the root growth of the crop, and also because the dropper has a certain direction with respect to the hose, there is a problem that the water supply only around the dropper is not suitable for growing crops.

The improved drip irrigation method in this case is to install a dropper in the hose and supply water by drilling a fine hole in the hose, for example, the Republic of Korea Utility Model Publication No. 1998-0065642 and the Republic of Korea Utility Model Registration No. 0322935 Can be mentioned.

However, the above designs are limited in size, because the dropper is configured in a part of the hose, so the maze for depressurizing the water acting in the hose is very narrow.

As a result, the reduced pressure labyrinth with complex bends has a condition in which impurities such as iron, phosphorus, and calcium contained in the water are deposited and fixed, and the labyrinth is easily blocked, and in particular, iron ions are oxidized while passing through the reduced pressure labyrinth. There is a closed end where iron rust is fixed and the labyrinth is closed, and even when the hose is buried in the ground, the water is behind the dropper covered by the hose because the dropper discharges water in only one direction to the hose outer diameter. Has a problem that it is not sufficiently supplied.

Accordingly, the present invention, which is provided to overcome the above-mentioned problems, minimizes the phenomenon of the maze blocked by the fine impurities contained in the water while sufficiently reducing the water pressure in the hose, thereby extending the durability life and supplying the water evenly. Its purpose is to.

In addition, the present invention has another object to supply sufficient water in a uniform distribution over a larger area without the blind area where water is not supplied only around the hose even when the hose is buried underground.

The drip irrigation structure of the present invention for achieving the above object has a cylindrical shape such that the dropper is compressed and embedded in the inner diameter of the hose, and the sealing portion is protruded in the longitudinal end, and the outer peripheral surface of the hose A pressure reducing unit is formed to receive a portion of the water flowing in the water to sufficiently reduce the water pressure through many curved paths, so that the pressure-reduced water is discharged to the outside through at least two micropores installed in the hose.

In addition, the pressure-reducing unit, which is a fine labyrinth formed in the dropper, is oxidized by iron ions or the like contained in the water to prevent iron rust from being clogged.

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

1 is a perspective view showing a state in which the dropper according to the present invention is built in the hose.

Referring to FIG. 1, a dropper 10 as shown at predetermined intervals is installed inside a watering hose 1 for supplying water required for growing a crop, and the dropper 10 is installed. At least two micropores 2 are provided at the both ends in the longitudinal direction to discharge water in the hose 1.

In order to make the water discharged into the micropores 2 drip, it is necessary to significantly reduce the water pressure of the water flowing into the watering hose 1.

Therefore, the dropper 10 is to take a small amount of water to be discharged by decompression along the labyrinth in which many bends are formed, such a dropper is embodied in FIG.

2 is an overall perspective view of the dropper according to the present invention.

The dropper 10 with reference to FIG. 2 is cylindrical in shape so that it may be crimped easily with respect to the whole inner diameter surface of the hose 1, and the both ends of the dropper 10 in the longitudinal direction are the said hose 1 Sealing part 17 is provided to be bonded to the inner surface of the protruded in a circular shape so that water does not leak, the central predetermined portion is provided with a perforated inlet for guiding the water flowing into the flowing water portion 11 to the outer peripheral surface of the dropper 10 ( 12) is provided.

The structure of the dropper 10 for depressurizing the water received from the inlet 12 is as follows.

The outer circumferential surface of the dropper 10 is formed with a decompression unit 13 having a large number of bent portions as shown in the drawing, so that water flowing from the inlet 12 proceeds along the maze of the decompression unit 13. The pressure of the water is largely reduced in pressure, and the parts protruding from the pressure reducing part 13 are compressed on the inner surface of the hose 1 so that the water does not flow out.

A pressure reducing part 13 is also formed on the rear surface (not shown) of the illustrated dropper 10, and the water passing through the pressure reducing part 13 is located at the top center of the illustrated dropper. Guided to the pressure reducing outlet 14 is distributed to both sides in the longitudinal direction of the dropper 10 through the distribution section 15 path.

The dispensed water is filled in the storage unit 16 located between the sealing unit 17 and the decompression unit 13, and the water pressure at this time is in a very low state so that the hose passes through the micropores 2 of FIG. It is discharged to the outside.

In order for the water discharged to the outside of the hose 1 to be supplied with sufficient area to the periphery of the hose, the longitudinal hole of the dropper 10 as shown in FIG. It is preferable to install at least one or more about each of the circumference of the hose (1) surrounding, and at this time, since the water is discharged in all directions with respect to the hose, there is no blind spot where water is not supplied.

On the other hand, the dropper 10 is generally injection-molded with a synthetic resin material in consideration of the ease of manufacture and the ease of price, the present invention is the oxidation of iron ions by electrical magnetic to the injection molding material (RESIN), the raw material of the dropper The injection molding was performed by adding 10 to 50% by weight of a mineral, for example, TOURMALINE, which prevents the growth of the mineral.

Tourmaline, also known as tourmaline, is a natural mineral, and when it comes into contact with water, a current of 0.06 mA is permanently generated, which causes alkali ionization of water through electrolysis of water, and generates surfactants. It is known to generate over-infrared rays.

Such a water activator is not limited to tourmaline, and is a mineral or a synthetic or purified substance that prevents the oxidation of iron ions by electrical magnetism to improve water quality through contact with water due to its physical properties without additional devices. If it is a substance, it is also possible to add other substances.

When injection molding the dropper 10 by adding tourmaline, which is an example of such an action, the dropper not only improves the water pressure during the depressurization process but also improves the water quality during the depressurization process, and prevents the dropper 10. The pressure portion 13 of the to prevent the phenomenon is clogged by the corrosive.

Furthermore, since tourmaline has a characteristic that the purification ability is doubled when a pressure or an impact is applied, the purification ability is naturally improved by the water pressure generated when the water passes through the depressurization unit 13 formed of the fine curved maze. .

According to the drop structure according to the present invention, while the dropper sufficiently depressurizes the water pressure in the hose and prevents the oxidation of the iron ions contained in the water by the dropper containing the tourmaline, the phenomenon that the decompression maze is not clogged, Furthermore, the service life of the drip drainage system is extended.

In addition, even when the hose is buried in the ground, at least one fine hole is installed at both ends of the dropper and around each tip, so that a larger area without the occurrence of blind spots where no water is supplied around the hose is provided. It is a very useful design that can provide a constant and sufficient water supply.

1 is a perspective view showing a state in which the dropper according to the present invention in the hose.

2 is a perspective view of the dropper according to the present invention.

Explanation of symbols on the main parts of the drawings

1: Hose 2: Fine hole

10: dropper 11: flowing water

12: inlet port 13: pressure reducing unit

14: decompression outlet 15: distribution unit

16: storage 17: sealing (Sealing)

Claims (2)

In the structure for draining the water installed in the watering hose for crop cultivation, The cylindrical dropper 10 pressed against the entire circumference of the hose 1 includes: a sealing portion 17 brought into contact with the inner surface of the hose at the longitudinal end thereof; An inlet 12 drilled to take water on the outer circumferential surface; A bending decompression unit 13 for depressurizing water; A distribution section 15 for dividing the reduced pressure water at both ends; And a storage unit 16 formed along the circumferential surface of the dropper on both sides of the sealing unit 17 and the pressure reducing unit 13 to store dispensing water. Droplet irrigation structure for crop cultivation, characterized in that at least one fine hole (2) is formed at each position of the hose surface. The method according to claim 1, The dropper is injection-molded with synthetic resin, the drip irrigation structure for crop cultivation, characterized in that the torumarin is mixed by 10 to 50% by weight.