KR20200029798A - injection devices for fluid - Google Patents

Abstract

The present invention relates to a fluid spray device capable of spraying fluid over a wider area, which provides a strong rotational force to fluid to be sprayed so that the fluid can be sprayed over a wide area. Moreover, the fluid spray device can freely control an area where the fluid is diffused by replacing a flow path plate installed therein.

Description

Fluid ejectors {injection devices for fluid}

The present invention relates to a fluid ejector, and more particularly, to a fluid ejector that enables ejecting the ejected fluid into a wider area.

Particularly, the present invention relates to a fluid ejector capable of freely adjusting an area in which fluid is diffused by exchanging a flow path plate installed therein, by providing a strong rotational force to the fluid to be ejected.

Various devices have been used in various fields to spray and supply a liquid containing water and a gas containing air (hereinafter referred to as “fluid”) to a desired place.

As a means for supplying such a fluid to a predetermined space, a nozzle or an injector (hereinafter referred to as “injector”) is used, and various techniques for supplying the required amount to the desired area have been developed.

In the case of water or disinfectant, it should be able to supply evenly to a wide area as much as possible. To this end, sprinklers are mainly used for general roads, and various spraying devices have been developed for water supply to agricultural crops, spraying pesticides, and disinfection or cooling of housing facilities. Is being used.

Examples of technologies related to such injectors include Patent Documents 1 to 3, wherein Patent Document 1 includes a first member having a first flow path in a straight form and a first inclined surface in the form of a truncated cone for spraying a fluid; And a second member coupled to the outside of the first body and having a second inclined surface in surface contact with the first inclined surface, wherein a second flow path of a spiral or curved shape is formed on the first inclined surface or the second inclined surface. It is combined with the fluid injected from the to form a flow of fluid injected in a vortex form,

Patent Literature 2 includes a tubular inner unit in which the first fluid flow path is formed in the longitudinal direction, a tubular intermediate unit in which the inner unit is spaced and inserted therein, and a tubular outer unit in which the intermediate unit is inserted into the gap. Including, the elongated space of the annular cross-section due to the clearance between the inner unit and the intermediate unit and the elongated space of the annular cross-section due to the clearance between the intermediate unit and the external unit respectively define the inner second fluid passage and the outer second fluid passage. To define,

Patent Document 3 is formed on one end of the nozzle, the first inlet through which the first fluid flows; A first injection port that injects a first fluid flowing from the first inlet and flowing along the flow path formed along the central axis of the nozzle; A second inlet port formed on a side of the nozzle and into which a second fluid flows; A second injection port for injecting a second fluid flowing from the second inlet and flowing along the flow path formed in the nozzle toward the first fluid injected through the first injection port; And a plurality of holes formed in the cap covering the first injection hole, the second fluid flowing through the flow path formed in the nozzle and flowing through the first injection hole and the second injection hole, and mixed through the first injection hole and the second injection hole. It includes a third injection port that is injected toward the first fluid and the second fluid.

Although various fluid injectors have been developed as described above, they are difficult to manufacture due to a complicated structure, and there are disadvantages in that fluid is not evenly sprayed in a desired area and control of the injection area is difficult.

Republic of Korea Patent Publication No. 10-2010-0088473 Republic of Korea Patent Publication No. 10-2016-0072457 Republic of Korea Patent Publication No. 10-2011-0039040

The present invention has been developed to solve the problems of the prior art as described above, and has a simple structure, and it is an object of the present invention to provide a fluid ejector capable of ejecting a fluid to be ejected into a wider area as well as being easy to manufacture. .

In particular, the present invention is to provide a fluid ejector capable of freely adjusting the area in which the fluid is diffused by exchanging a flow path plate installed therein to give a strong rotational force to the fluid to be ejected, and to distribute the fluid to a wide area. do.

The fluid ejector according to the present invention for solving the above object is a fluid ejector for ejecting a fluid over a wide area, the fluid inlet space is formed and the main body is formed with an inlet for fluid to flow into one side; A cover which is detachably installed in the fluid inflow space of the main body and is formed with an injection hole through which fluid is ejected in the center; And a plate body shape and installed inside the body and the cover to guide the fluid introduced into the inlet of the body to the injection hole of the cover, and a central rotation channel is formed in the center corresponding to the injection hole formed in the cover, A flow path plate is formed on the surface of the at least one inlet hole formed by passing through the flow path plate formed with at least one induction channel to supply the fluid flowing into the inlet hole to one side of the central rotation channel so that the fluid is rotated in the central rotation channel. It is characterized by.

The inflow hole may be further formed in a circular shape on the inflow hole side of the induction flow path, and the induction flow path is preferably connected in a tangential direction to the inflow flow path.

An acceleration flow path may be further formed between the inflow hole and the inflow rotation flow path, and the acceleration flow path is preferably connected to the inflow rotation flow path in a tangential direction.

The fluid ejector according to the present invention has a simple structure and is easy to manufacture, thereby providing an effect at a lower price.

In addition, the present invention has the effect of evenly supplying the ejected fluid to a wider area.

In addition, the present invention not only has an effect that the fluid can be evenly sprayed over a wide area by giving a strong rotational force to the fluid being sprayed, but also has the effect of freely adjusting the area where the fluid is diffused by replacing the flow path plate installed therein. .

1 is an exploded perspective view of an example of a fluid ejector according to the present invention
Figure 2 is a cross-sectional view of different examples of the fluid ejector according to the present invention
Figure 3 is a perspective view of different examples of the flow path plate constituting the fluid ejector according to the present invention
Figure 4 is a perspective view of different examples of the fixing means for fixing the fluid ejector according to the present invention

The present invention can be applied to various changes and can have various embodiments, and specific embodiments will be illustrated in the drawings and described through detailed description. However, this is not intended to limit the present invention to a specific embodiment, it should be understood to include all modifications, equivalents, and substitutes included in the spirit and scope of the present invention.

In describing each drawing, similar reference numerals have been used for similar components, and in the description of the present invention, when it is determined that detailed descriptions of related well-known technologies may obscure the subject matter of the present invention, detailed descriptions thereof will be omitted.

The present invention has a simple structure, and is easy to manufacture, so that it can be provided at a lower price, and it can uniformly supply the ejected fluid to a wider area.

The fluid ejector 1 according to the present invention is a fluid ejector that ejects a fluid over a wide area, as shown in FIGS. 1 and 2, where a fluid inflow space 10a is formed and fluid is introduced into one side ( 11) the main body 10 is formed; A cover 20 detachably installed in the fluid inflow space of the main body and having a spray hole 21 through which fluid is injected in the center; And a plate body shape and installed inside the body and the cover to guide the fluid introduced into the inlet of the body to the injection hole of the cover, and the central rotation passage 33 in the center corresponding to the injection hole 21 formed in the cover. ) Is formed, is formed on the surface of the central rotation flow path of the at least one inflow hole 31 formed through the plate to supply the fluid flowing into the inflow hole to one side of the central rotation flow path so that the fluid is rotated in the central rotation flow path It comprises a flow path plate 30 is formed with one or more induction passage 32.

The fluid ejector 1 of the present invention is made of a high-strength metal or synthetic resin, and the fluid receives rotational force while passing through a flow path formed in the flow path plate 30, so that the ejection pressure is high and can be sprayed in a wide area. .

1 and 2, the main body 10 is formed with a fluid storage space 10a in which water introduced from the inlet 11 is stored, and can be disassembled and assembled with the cover 20. The assembly part 10s is provided so as to be provided.

As shown in FIG. 1, the assembly portion 10s has a thread formed on an outer circumferential surface, and an assembly portion 20s having a thread formed on a lower inner circumferential surface of the cover is provided.

The cover 20 serves to guide the fluid passing through the flow paths of the fluid receiving space 10a and the flow path plate 30 of the main body so as to be ejected in a certain direction, and the injection hole 21 is formed at the center. , The injection hole 21 may be formed in various forms as shown in FIG. 2, and the injection hole formed in this way allows the ejected fluid to be injected into a wider area.

The injection hole 21 is manufactured in a form that gradually decreases in width from inside to outside as shown in FIG. It can be based on, and as shown in FIG. 2 (b), in the middle of the injection hole toward the inside and outside and gradually widening, when it is formed to be widened, it is sprayed at high pressure, but the fluid is sprayed along the outside slope You can also spread this wide.

In addition, the injection hole 21, as shown in Fig. 2 (c), a secondary injection hole (21s) is formed with a trumpet-shaped hole widening toward the outside so as to be detachably attached to the outside of the gradually narrowing hole toward the outside As it is further installed, it may be possible to adjust the injection pressure and the injection region.

As illustrated in FIG. 2, the flow path plate 30 is installed inside the body 10 and the cover 20 assembled, and the flow path of the flow path plate 30 is formed on the inner wall of the cover. It becomes in close contact and the fluid moves along the flow path and is ejected into the injection hole 21.

The flow path plate 30 may be configured in various forms as shown in FIG. 3, first, as shown in FIG. 3 (a), the flow path plate 30 is formed through an upper and lower flow path of the flow path plate ( 31) is formed, and an induction flow path 32 and a central rotation flow path 33 are formed on the upper surface connected to the inflow hole.

Two or more of the inflow holes 31 are formed to be symmetrical with respect to the center rotation flow path 33 formed in the center of the upper surface as shown, and the guide flow path 32 between the central rotation flow path and the inflow hole Is formed.

The central rotation flow path 33 has a circular shape as shown in the figure, and when the inflowing fluid flows into one wall of the circular space, it moves along the wall of the circular groove to apply rotational force to the fluid. The induction passage 32 is connected in a tangential direction to the central rotation passage 33 as shown.

In addition, as shown in FIG. 3 (b), an inflow rotating flow passage 34 may be further formed in a circular shape on the inflow hole 31 side of the induction flow passage 32, and the inflow rotation flow passage 34 is illustrated in FIG. 2. As shown in the figure, the planar shape has a circular shape, so that the fluid flowing from the inflow hole 31 rotates in this space and moves toward the induction passage.

The induction flow path 32 was accelerated as the fluid flowing from the inflow hole moved in the tangential direction as it was connected to the inflow rotation flow path in the tangential direction.

In addition, as shown in Figure 3 (c), the inlet hole 31 and the inlet rotating passage 34, an acceleration passage 35 may be further formed, the acceleration passage 35 is the inlet rotation passage It is connected tangentially to.

As the acceleration flow path is formed, the fluid flowing into the inflow hole is supplied to the inflow rotation flow path through the acceleration flow path, and the rotational force is applied, and as the rotational force is applied, the accelerated fluid is fed back to the central rotation flow path. The fluid ejected through the injection hole formed in the upper portion can be discharged at a higher pressure and high speed.

In addition, the fluid ejector 1 according to the present invention may further include a fixing means 40 as shown in FIG. 4, wherein the fixing means 40 is fixed to the fluid ejector of the present invention in various places. For the purpose, as shown in Figure 4 (a), the end may be formed in the shape of a pointed pile, which is used to be fixed to the ground of a road such as a golf course or ginseng field.

Another example of the fixing means is to install the support plate at the bottom as shown in Figure 4 (b), which is used to install a fluid ejector on a flat surface that can not be piled, the fixing shown in Figure 4 (c) Sudan has been installed on structures installed in houses, pig houses, poultry houses, etc., and is equipped with a retaining ring so that it can be fixed to a frame fixing these facilities.

1: fluid jet
10: body 10a: fluid inlet space
10s: assembly
11: inlet
20: cover 20s: assembly
21: injection hole 21s: auxiliary injection hole
30: Euro version
31: Inflow hole 32: Induction passage 33: Central rotation passage
34: inflow rotation flow path 35: acceleration flow path
40: fixing means

Claims (3)

In the fluid ejector (1) for spraying a fluid over a wide area,
A body 10 in which a fluid inflow space 10a is formed and an inlet 11 through which a fluid flows is formed;
A cover 20 detachably installed in the fluid inflow space of the main body and having a spray hole 21 through which fluid is injected in the center;
It is formed in a plate shape, is installed inside the body and the cover to guide the fluid flowing into the inlet of the body to the injection hole of the cover, the central rotation flow path (33) in the center corresponding to the injection hole 21 formed in the cover ) Is formed, is formed on the surface of the central rotation flow path of the at least one inflow hole 31 formed through the plate to supply the fluid flowing into the inflow hole to one side of the central rotation flow path so that the fluid is rotated in the central rotation flow path A fluid ejector, characterized in that comprises a; flow path plate (30) is formed with at least one induction passage (32).
According to claim 1,
A fluid ejector characterized in that the inflow channel 31 is further formed in a circular shape on the inflow hole 31 side of the induction channel 32, and the induction channel 32 is tangentially connected to the inflow channel.
According to claim 2,
A fluid ejector characterized in that an acceleration flow passage (35) is further formed between the inflow hole (31) and the inflow rotation flow passage (34), and the acceleration flow passage (35) is tangentially connected to the inflow rotation flow passage.

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