KR200291385Y1 - Diversion hose having vibrating plate - Google Patents

Abstract

The present invention relates to a fountain hose having a vibration plate to adjust the distance that the water is discharged through the fountain hole formed in the fountain hose according to the restoring force of the vibration plate and the change of the jet pressure.

The fountain hose for this purpose, in a fountain hose that is punctured a plurality of fountain holes along the outer surface, the vibration is cut to have a scale or cross groove in the fountain hole to vary the ejection distance by varying the ejection pressure of the fluid to be ejected It is characterized by having a plate. As a result, the spraying pressure is prevented from being significantly reduced by the fountain hose provided with the vibration plate to prevent the pressure drop, thereby spraying and supplying water to a long distance.

Description

Fountain hose having vibrating plate

The present invention relates to a fountain hose having a vibration plate, and relates to a fountain hose having a vibration plate to adjust the distance of the water discharged through the fountain hole formed in the fountain hose according to the restoring force of the vibration plate and the change of the jet pressure will be.

Hoses are commonly used for agricultural irrigation. Water drawn from a source such as a motor is moved to a desired place through the hose and sprayed on crops or the like by using a separate injection means. In particular, a fountain hose is used to directly supply crops or grass while water is being moved, without using the separate injection means.

In general, the fountain hose has a configuration such that the water is ejected through the injection hole formed in the side wall in the hose under a certain pressure. The fountain hose is configured such that one or more injection holes form a group at regular intervals, and the groups are arranged so that water is ejected.

However, when water is ejected through two or more holes formed on the left and right sides of the conventional fountain hose and is separated from the supply source, the ejection pressure is rapidly lost and it is difficult to transport the water to a long distance. Accordingly, in order to transfer the water to a long distance, it was necessary to use a pressurization device having a high pressing force or to install a pressurization device in the middle separately, but in this case, there was a problem in that a cost factor occurred with the addition of a facility.

In addition, when the pressure at the time of supply is increased in order to prevent the loss of the ejection pressure, the hose around the hole is increased due to the high pressure, which lowers the ejection pressure or, in severe cases, causes the hose to be torn.

The type of hose proposed to solve this problem is disclosed in FIG. 8. Referring to FIG. 8, the nonwoven fabric 56 is inserted into the vinyl hose 50. When the water is filled in the hose 50, the nonwoven fabric 56 is directed to one of the hose surface 52, and the introduced water is passed through the air gap of the nonwoven fabric 56, and the pressure is reduced. In addition, the nonwoven fabric 56 reduces the pressure of the water jetted through the fountain hole 58 so that the water pressure formed in the hose 50 does not directly act so that the fountain surface 58 and the hose surface around it are stretched or torn. Solved the problem.

By the way, the non-woven fabric 56 described above can prevent the hose 50 from being stretched, but the spray pressure is not maintained as before, so that the water is not evenly sprayed over the perspective, and causes the problem of being sprayed only in close proximity. . In addition, although the fountain hole 58 is formed in the hose surface 52 which is depressurized by the nonwoven fabric 56, no elongation or rupture of the hose occurs, but relatively excessive pressure is applied at the opposite hose surface 54. Action, causing a problem of rupture.

In addition, in the above-described fountain hoses, the sprayed water is sprayed and supplied in the form of water droplets, so that the sprayed water is not directly sprayed on the plant, but touches the back of the leaf after being fried on the ground of the growing space. In this case, various pathogens contained in the soil will be attached to the leaves and contaminated with water, eventually causing the disease (해).

An object of the present invention for solving the above problems, using a fountain hose equipped with a vibration plate to prevent the pressure drop to provide a vibration plate for evenly spraying water to a long distance in the state that the injection pressure is significantly reduced. It is to provide a fountain hose having.

Another object of the present invention is to provide a fountain hose having a vibration plate to adjust the perspective of the sprayed water by changing the restoring force of the vibration plate in accordance with the pressure change in the fountain hose to distribute the water evenly.

Still another object of the present invention is to provide a fountain hose having a vibration plate that allows water to be sprayed in a mist state to prevent contamination of soil pathogens by water droplets.

1 is a view showing an embodiment of a fountain hose having a vibration plate of the present invention.

2 is a view showing the structure of the wing and the partition wall portion of the jet pressure adjusting mechanism of FIG.

3 is a view for showing the structure of a fountain hose having a vibration plate of the present invention.

4a and 4b is a view showing an embodiment of the fountain hose and the ejection path of the fluid according to an embodiment of the present invention.

5 is a view showing another embodiment of a fountain hose according to an embodiment of the present invention.

6 is a view showing an example of using the fountain hose according to an embodiment of the present invention.

FIG. 7A is a view for explaining a hose having a linear shaking plate and a shaking form. FIG.

FIG. 7B is an enlarged view illustrating a state of part A when water is ejected from the shaking plate of FIG. 7A.

8 is a cross-sectional view showing an example of a hose in which a nonwoven fabric is inserted among conventional fountain hoses.

* Explanation of symbols for the main parts of the drawings

10 housing 12 wing

13 bulkhead 14 through hole

16: inlet 18: outlet

20a: supply layer 20b, 20d: coating layer

20c: teaching fabric layer 22: shaking plate

24: hose body 26: fountain ball

100: ejection pressure regulating mechanism 200: fountain hose

Fountain hose having a vibration plate of the present invention for achieving the above object, in the fountain hose is a plurality of fountain holes perforated along the outer surface, the fountain hose is made of a polyethylene coating layer coated on the inner and outer surfaces of the fabric and the fabric And, characterized in that the fountain hole is made of a cutting plate to be cut to vary the ejection distance by varying the ejection pressure of the fluid to be ejected.

According to a preferred embodiment of the present invention, the shaking plate may have a scale shape arranged along the longitudinal direction of the fountain hose, and may be composed of cross-cut grooves. The polyethylene coating layer maximizes the shaking effect. It is desirable to have a high density coating on the inner surface of the hose.

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

The embodiments of the present invention described below are merely intended to illustrate the technical idea of the present invention by way of example, it should not be understood that the scope of the present invention is limited thereto. Various modifications, changes and variations are possible in the following examples which will be apparent to those of ordinary skill in the art.

In an embodiment of the fountain hose having a vibration plate of the present invention, referring to FIG. It is coupled to the fountain hose 200 is supplied to the part is provided with a jet pressure control mechanism 100 so that the pressure of the fluid discharged from the fountain hose 200 is periodically different with the passage of time.

The fountain hose 200 is formed in the hose body 24, the fountain hole 26 is formed on one side of the hose body 24 so that the fluid flows in, and the pressure state inside the hose body 24 Accordingly, the shaking plate 22 is formed to open and close the fountain hole 26. The shaking plate 22 is preferably formed at a position of the upper middle portion of the fountain hose 200, and is formed with a scale or an inverted scale so that the fluid is ejected to the outside according to the change in pressure.

The jet pressure control mechanism 100 is composed of a cylindrical housing 10, the housing 10 is again provided with an inlet 16 and outlet 18 are coupled to each other by a screw coupling method, etc. It is. The housing 10 includes a partition wall 13 in which a through hole 14 is formed, and a wing 12 fixed to the partition wall 13 to rotate.

The fountain hose of the present invention having such a configuration, in addition to the structure shown in the fountain hose 200 presented in this way, various types of fountain hose can be used, and if it has a structure that can supply water to the object is not limited in kind Do not.

2 is a front view showing an example of the ejection pressure adjusting mechanism 100 of the embodiment according to the present invention, in which a partition wall 13 is formed inside the housing 10, and the partition wall 13 has a through hole 14. It can be seen that it is formed symmetrically. Then, the blade 12 is rotated around the center of the housing 10, the blade 12 is rotated by a period of time, the operation of opening or closing the through hole 14 is repeated. In particular, the rotation operation of the blade 12 is the time that the fluid supplied to the fountain hose 200 is supplied with a constant magnitude of pressure and the time that the pressure is supplied in a state that the pressure is released or reduced pressure alternately the fountain hose The blowing pressure is changed by the pressure change inside the 200. This varies the ejection pressure of the fluid ejected through the vibration plate 22 and at the same time changes the restoring force of the vibration plate 22. Therefore, the reach of the ejected fluid is eventually adjusted to vary with time. In this way, the supply of the fluid is made uniformly according to the distance, so that the supply of the fluid can be made evenly.

At this time, the rotation operation of the blade 12 may be controlled by various methods. For example, as described above, the mechanical structure, or by using a separate control means by combining a motor (Motor) or an actuator (Actuator) to the blade 12 to adjust the number of revolutions over time, By adjusting the opening and closing degree, the pressure of the fluid supplied to the fountain hose 200 is adjusted.

3 is a view showing a structure of a fountain hose having a vibration plate of the present invention.

A supply layer 20a through which a fluid is supplied is formed inside, and on the outside thereof, a high density coating layer 20b, a polyethylene interwoven fabric layer 20c, and a low density coating layer 20d are sequentially stacked to form a fountain hose 200. .

Thus, the shaking plates 22 having a size that allows the fluid to be ejected are formed in the upper middle portion of the fountain hose 200 having the stacked structure. In this case, the shaking plate 22 may be formed by various methods, and after forming the shaking plate 22 in the original state before processing with a hose, forming the fountain hose 200 by bonding or shaking plate 22. ) To form a fountain hose 200 by forming the shaking plate 22 using a laser or other processing means after the production of the hose in the state that does not form.

The high-density coating layer 20b and the low-density coating layer 20d are formed on the inner and outer surfaces of the fountain hose 200, respectively, so that the restoring force of the vibration plate 22 can be improved. In other words, the teaching fabric layer 20c is provided. In the case of the hose coupled with only the low density coating layer 20d, the elastic flexibility is maintained, so that the opening and closing operation of the shaking plate 22 is alleviated, thereby showing a phenomenon in which the fountain hole 26 is maintained in an open state. However, when the high-density coating layer 20b is coated on the inner surface of such a hose, the elasticity around the fountain hole 26 and the vibration plate 22 is cut off, so that the vibration plate 22 does not open at a predetermined pressure or lower, and in the hose, When the pressure is applied, the vibrating plate 22 shows an open state. The vibrating plate 22 tries to close the fountain hole 26 opened by the strong restoring force of the high-density coating layer 20b. Repeated shaking caused by the pressure of the water is generated, causing a so-called spray phenomenon to decompose water particles released through the fountain hole 26.

Figure 4a is a planar cross-sectional view showing an example of the fountain hose 200 of the present invention, the fountain hose 200 has a form in which one side of the hose body 24 is cut, the shaking plate 22 in the cut portion And a fountain hole 26 is formed. As a result, the fluid introduced into the hose body 24 is discharged to the outside by the pressure through the fountain hole 26 because a pressure having a predetermined size is formed. When pressurized, the fluid is ejected to the far and the maximum, and when depressurizing, the repulsive plate 22 is forced to return to a circular shape so that the fluid can be ejected at a close distance.

4b shows that the fountain hole 26 is formed on one side as well as the other side of the fountain hose 200 as a modified form of the fountain hose 200. When the fountain hose 200 is configured as described above, the fluid is supplied in both directions, but the pressure is set to change with time, so that the fluid can be evenly supplied to a large area.

In addition, Figure 5 is a view showing another example of the fountain hose 200 of the present invention shows the form of the 'X' shape in which the shape of the fountain hole cross-shaped incision grooves are formed. In addition, a vibration plate having various shapes may be formed, for example, the shape of the U-shaped, V-shaped, etc. is not limited.

In the example of the fountain hose 200 described above is to illustrate a configuration for further easier pressure control of the jet pressure adjusting mechanism 100, otherwise the fountain hole in the hose body 24 only without the vibration plate 22 Applicable even if formed.

6 is a view illustrating a specific embodiment of a fountain hose having a vibration plate according to the present invention having such a configuration.

Referring to FIG. 6, it can be seen that the variable pressure is generated inside the fountain hose 200, and thus the reaching distance is changed after the fluid is ejected. That is, when the pressure is maximized in the state in which the through hole 14 of FIG. 2 is fully opened, the reach of the fluid reaches the position of 'A'. Then, when the wing 12 is gradually rotated to cover the through hole 14, the pressure formed inside the fountain hose 200 is minimized, and the distance that the fluid is ejected reaches the position of 'C' through 'B'. do. When the wing 12 is further rotated, the through hole 14 is gradually opened while gradually increasing the pressure inside the fountain hose 200 to reach the position of 'A' through the 'B'.

As a result, the ejection pressure of the fluid is changed according to the embodiment of the present invention, and thus the supply of the fluid is uniformly achieved by the time of arrival.

7A and 7B, as an embodiment of the present invention, an example in which a single-shaped shake plate 22 is formed and a diagram for explaining its operation are disclosed.

The straight shaking plate 22 formed at one side of the fountain hose 200 is normally closed, but when water is filled in the fountain hose 200, a predetermined pressure is formed therein, and eventually through the shaking plate 22. It is opened to the extent that water is discharged. As shown in FIG. 7B in which the portion 'A' of FIG. 7A is enlarged, water is ejected to the outside through the fountain hole 26 by the pressure in the shaking plate 22. By the way, the vibration plate 26 is shaken as a reaction force that tries to maintain the tension plate 22 to be taut in response to water pressure. As a result, water is sprayed near the fountain hose 200 in the form of mist, not in the form of a body of water, by the shaking of the shaking plate 22 at the incision start portion of the fountain hole 26 in the water ejected through the fountain hole 26. In addition, since the repulsive force acts relatively lower than the central portion of the shaking plate 22, water is injected far.

As a result, the water is supplied in the form of mist or fine water particles, so that the plant does not cause damage to branches or leaves due to the water supply, and also prevents the contamination of pathogens by the conventional water falling back to the ground. . Such an effect is similarly obtained even in the case of the above-mentioned scaled shake plate and cut-away shake plate.

According to the present invention, it is prevented that the injection pressure is significantly reduced by the fountain hose provided with a vibration plate to prevent the pressure drop, and there is an effect of spraying and supplying water to a long distance.

The perspective of the sprayed water is controlled by changing the restoring force of the vibration plate according to the pressure change in the spray hose, so that water is evenly sprayed.

By periodically providing pressure to the fluid supplied into the fountain hose, the ejection distance of the fluid supplied through the fountain hole is changed, and the fluid can be evenly sprayed.

In addition, since the contamination of the pathogens by the water back to the conventional ground by the water supplied in the spray form is prevented in advance, it is possible to obtain the effect of preventing the disease.

Claims (6)

In the fountain hose, a plurality of fountain holes are drilled along the outer surface, The fountain hose is made of a fabric and a polyethylene coating layer coated on the inner and outer surfaces of the teaching material, and to configure the fountain hole cut in the shaking plate to vary the ejection distance by varying the ejection pressure of the fluid ejected through the fountain hose A fountain hose with a vibration plate characterized by the above. The method of claim 1, The vibrating plate is a fountain hose having a vibrating plate, characterized in that it has a scale form arranged along the longitudinal direction of the fountain hose. The method of claim 1, The vibrating plate is a fountain hose having a vibrating plate, characterized in that it consists of a cross-cutting groove arranged along the longitudinal direction of the fountain hose. The method of claim 1, The vibrating plate is a fountain hose having a vibrating plate, characterized in that it has a straight incision hole arranged along the longitudinal direction of the fountain hose. The method of claim 1, The polyethylene coating layer is a fountain hose having a shaking plate, characterized in that the inner surface of the hose has a high-density coating layer to maximize the shaking phenomenon. delete