KR101983092B1 - Liquid spraying module and spraying device using thereof - Google Patents

Abstract

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a liquid jetting module and a jetting apparatus including the same, and more particularly, to a liquid jetting apparatus and a jetting apparatus including the same, It is. According to the present invention, by making the particle size of the sprayed liquid (for example, hydrogen or sterilizing water) smaller, it is possible not only to increase the reactivity with the fine particles, but also to increase the water content It is possible to spray evenly, thereby further enhancing the sterilizing effect on the object and visually providing a fantastic spraying effect.

Description

Technical Field [0001] The present invention relates to a liquid spraying module and a spraying device including the same,

The present invention relates to a spray module used for spraying a liquid, and more particularly, to a spray module capable of spraying a liquid into fine particles smaller in size and an injection device including the spray module.

Recently, environmental pollution has increased and the possibility of various environmental diseases has been increased. In the living environment around us, various kinds of microorganisms such as general bacteria such as Escherichia coli, yeast, bacteria, fungi, It floats in the air or attached to the wall, and is present in large quantities, threatening the health life.

Also, even in a residential environment, various microorganisms such as a refrigerator, an air conditioner, a shoe inside, a pet, etc. are abundant, and harmful microorganisms adhere to and exist in the hands, feet, face and mouth of a human body. Strong sterilization is strongly required. As a result, interest in healthy life (well-being) is increasing day by day. In order to maintain a well-being life, technologies for sterilizing and cleaning electrolytic water generated by electrolysis of water have been developed and widely used.

As an example of such a technique, Korean Patent Registration No. 10-1653189 (entitled "Portable Micro-dust Removal Sterilizing Spray Gun Using Hydrogen Water") will be described as follows. When power is supplied from a power supply main body, A power supply for generating electric power to be supplied to the electrode module, a coupling member for coupling or detachably installed at the lower end of the electric power supply unit to be coupled to the storage container, A spray nozzle fixed to the front of the electric power supply unit and capable of spraying the hydrogen water sucked from the hose and extending rearward of the electric power supply unit, And a handle for controlling the operation of the hose and the spray nozzle.

This prior art technology has an advantage in that it can instantaneously generate hydrogen water having excellent sterilizing power and spray generated hydrogen water in a place where sterilization is required in a real life. However, the spray nozzle used in the above-mentioned prior art has been used in conventional sprayers, so that there is a disadvantage that the water spray can not be decomposed into smaller particles. By making the particle size of the sprayed water smaller, it is possible not only to increase the reactivity with the fine particles but also spray the water even more uniformly to the invisible fine portion, thereby further increasing the sterilizing effect on the object And it is possible to visually provide a fantastic spraying effect, so there is always a need to improve the spraying effect.

SUMMARY OF THE INVENTION The present invention has been made to solve the above-mentioned problems, and it is an object of the present invention to make the liquid to be delivered to the injection nozzle be whirled to further reduce the particle size of the liquid.

Further, through the present invention, by making the particle size of the sprayed liquid (for example, hydrogen or sterilizing water) smaller, it is possible not only to increase the reactivity with the fine particles, but also to increase the water content And more particularly, to a spray module capable of spraying more uniformly, a sterilizing effect on an object through the spray module can be further enhanced, and a visually fantastic spraying effect can be provided, and an injection device including the same.

The injection module according to the present invention comprises a nozzle bushing for conveying liquid by air pressure; An inflow port formed at one side of the cylindrical structure and through which the liquid transferred from the nozzle bush is introduced; and an inflow port formed in the tubular structure by a spring, Wherein the tubular structure includes at least one inlet opening and closing means for opening and closing the tubular structure, and at least one outlet formed at the other side of the tubular structure for discharging liquid introduced through the inlet, And two or more curve-shaped whirl-inducing grooves connected to the collecting grooves from the discharge port, respectively; And an injection cap having an inner surface which is in contact with the other side of the cylindrical structure and is inserted thereinto and has an ejection port for ejecting liquid to the outside at a position corresponding to the collection groove.

The injection nozzle includes a cylindrical structure having the other side surface of the cylindrical structure, a nozzle cap inserted into one side of the cylindrical structure, the inlet opening / closing means provided in the cylindrical structure, and the inlet opening / It is possible to include a spring to be inserted.

The inlet opening is formed in the center of one side of the nozzle cap and the inlet opening and closing means is provided in the longitudinal direction of the cylindrical structure inside the cylindrical structure and includes a head corresponding to the inlet and a head extending from the head And a support inserted into the spring.

In addition, the support may be shorter than the spring.

Preferably, the collecting groove is formed at the center of the other side of the cylindrical structure, and the discharge port is formed around the circumference of the collecting groove.

It is further preferable that the whirlpool inducing groove has a curved shape that narrows in the direction of the collecting groove.

In addition, the other side surface of the cylindrical structure can have a backflow preventing jaw formed along the outermost circumference.

Further, the backflow preventing jaws may be composed of an inner backflow preventing jaw and an outer backflow preventing jaw which are spaced apart from each other.

In addition, the whirlpool guide groove may be formed in a middle area including the center on the other side of the cylindrical structure, and the other side surface of the cylindrical structure may further include a flow guide groove formed around the center area, And the guide groove can be connected to the collecting groove from the outlet through the flow guide groove.

The outlet may be formed in the flow guide groove region or may be formed at a boundary portion where the flow guide groove region and the whirlpool guide groove are in contact with each other.

In addition, it is preferable that the flow path guide groove is formed in a deeper groove than the whirlpool guide groove on the other side of the cylindrical structure.

In addition, the whirlpool guide groove may have a bottom surface inclined from the end of the guide groove to the flow guide groove.

The channel guide groove may have a vertical side contacting the center region.

It is further preferable that three or more identical curved grooves having a predetermined radius of curvature are connected to the collecting grooves from three or more different points of the flow path guide grooves.

It is also possible that the three or more different points are symmetrical with respect to each other about the collecting groove.

In addition, the injection port of the injection cap may have a cross-sectional structure in which the inner surface is wide and the outer surface is narrow.

It is also preferable that the injection module according to the present invention is for a liquid atomizer.

In addition, another embodiment of the present invention is an injection device including the above-described injection module.

Further, the present invention may be an injection device, further comprising a storage container for storing water or sterilizing water to be delivered to the nozzle bushing of the injection module.

According to the present invention, the liquid to be conveyed is made to whirly through the whirl-inducing groove formed in the side surface of the injection nozzle and the collecting groove, thereby making it possible to further reduce the particle size of the liquid.

According to the present invention, by making the particle size of the sprayed liquid (for example, hydrogen or sterilizing water) smaller, it is possible not only to increase the reactivity with the fine particles, but also to increase the water content It is possible to spray evenly, thereby further enhancing the sterilizing effect on the object and visually providing a fantastic spraying effect.

1 is a perspective view showing an example of an atomizer used in the injection module according to the present invention,
FIG. 2 is a perspective view for explaining a use state of the injection module according to a preferred embodiment of the present invention, and FIG.
3 is an exploded perspective view of the injection module according to a preferred embodiment of the present invention,
4 is an exploded perspective view for explaining an example of the injection nozzle according to the present invention,
5 is a perspective view for explaining an example of a state in which a discharge port is formed in a cylindrical structure of an injection nozzle according to the present invention,
6 is a perspective view for explaining an example of a state in which a liquid forms a whirl on the other side of the cylindrical structure of the injection nozzle according to the present invention,
7 is a cross-sectional view for explaining an example of the internal structure of the injection module according to the preferred embodiment of the present invention.

BRIEF DESCRIPTION OF THE DRAWINGS The present invention is capable of various modifications and various embodiments, and specific embodiments are illustrated in the drawings and will be described in detail in the detailed description. It is to be understood, however, that the invention is not to be limited to the specific embodiments, but includes all modifications, equivalents, and alternatives falling within the spirit and scope of the invention. DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENTS Hereinafter, the present invention will be described in detail with reference to the accompanying drawings.

The terminology used in this application is used only to describe a specific embodiment and is not intended to limit the invention. The singular expressions include plural expressions unless the context clearly dictates otherwise. In the present application, the terms "comprises" or "having" and the like are used to specify that there is a feature, a number, a step, an operation, an element, a component or a combination thereof described in the specification, But do not preclude the presence or addition of one or more other features, integers, steps, operations, elements, components, or combinations thereof.

The terms first, second, etc. may be used to describe various components, but the components should not be limited by the terms. The terms are used only for the purpose of distinguishing one component from another.

1 is a perspective view showing an example of an atomizer used in the injection module according to the present invention.

The present invention relates to a spray module used for spraying a liquid, and more particularly, to a spray module capable of spraying a liquid into fine particles smaller in size and an injection device including the spray module.

The liquid is not particularly limited and may be ordinary water, a solution having a specific purpose, sterilized water, hydrogenated water, or the like. The liquid may be mixed or dissolved with predetermined solid particles or granules. The liquid may be an industrial oil, an automobile fuel, or the like.

In the following, water is described as the liquid, sterilized water or hydrogenated water is exemplified, but the present invention is not particularly limited thereto.

FIG. 2 is a perspective view for explaining a use state of the injection module according to a preferred embodiment of the present invention, FIG. 3 is an exploded perspective view of the injection module according to one preferred embodiment of the present invention, FIG. And is an exploded perspective view for explaining an example of the injection nozzle. FIG. 5 is a perspective view for explaining an example of a state in which a discharge port is formed in a cylindrical structure of the spray nozzle according to the present invention, FIG. 6 is a view showing a state in which a liquid forms a whirl on the other side of the cylindrical structure of the spray nozzle according to the present invention FIG. 7 is a cross-sectional view for explaining an example of the internal structure of the injection module according to the preferred embodiment of the present invention.

The injection module according to the present invention includes a nozzle bushing 100; An injection nozzle 200; And a spray cap 300 are included.

The nozzle bushing 100 conveys the liquid by air pressure. Specifically, the liquid is transferred by air pressure to the injection nozzle 200 according to the present invention. For this purpose, the nozzle bushing 100 may be connected to a separate reservoir for storing the liquid. The shape and size of the nozzle bushing 100 are not particularly limited and may vary depending on the type of product. For example, the nozzle bushing 100 may have a cylindrical structure, and may be connected to an injection nozzle 200 described later to transfer liquid to the injection nozzle 200.

The injection nozzle 200 is for making the liquid transferred from the nozzle bushing 100 into ultrafine particles and discharging the liquid into the injection cap 300 described later. In the present invention, the injection nozzle 200 has a cylindrical structure shape in which liquid transferred from the nozzle bushing 100 is transferred and discharged. That is, it has a cylindrical or cylindrical structure with an empty interior. Therefore, it may include the inlet opening / closing means 230 and / or the spring 240, which will be described later.

The injection nozzle 200 may be a single structure having a cylindrical structure and may include a cylindrical structure 210 and a nozzle cap 220 coupled thereto. That is, the injection nozzle 200 may include a cylindrical structure 210 having the other side of the cylindrical structure and a nozzle cap 220 inserted into one side of the cylindrical structure 210. For example, the injection nozzle 200 may have a tubular structure having a right side surface and a left side surface opposite to the right side in one cylindrical structure having both sides closed, and a side surface having one side (left side) 210 may be coupled to the nozzle cap 220 having one side (right side) of which is closed.

The injection nozzle 200 includes an inlet 221 formed at one side of the cylindrical structure and an outlet 211 formed at the other side of the cylindrical structure. The inlet 221 is formed at one side of the injection nozzle 200 or the cylindrical structure according to the present invention and the liquid received from the nozzle bushing 100 is introduced. The size and shape of the inlet 221 are not particularly limited and may be formed on one side of the nozzle cap 220. The inlet 221 is preferably formed in the center of one side of the injection nozzle 200 or the nozzle cap 220 for the smooth inflow of liquid by air pressure. The discharge port 211 is formed on the other side of the injection nozzle 200 or the cylindrical structure according to the present invention and discharges liquid introduced through the inlet 221. The size and shape of the discharge port 211 are not particularly limited and may be formed on the other side of the cylindrical structure 210 (see FIGS. 5 and 6). The discharge port 211 may be formed in the center area on the other side of the injection nozzle 200 or the cylindrical structure 210. However, as described later, the discharge port 211 is formed around the periphery of the center area, It is more preferable to make fine particles.

In addition, the injection nozzle 200 includes an inlet opening / closing means 230 and / or a spring 240 therein. That is, the injection nozzle 200 may include an inlet opening / closing means 230 provided in the cylindrical structure 210 and a spring 240 into which the inlet opening / closing means 230 is inserted. The inlet opening / closing means 230 opens and closes the inlet 221 by the spring 240 inside the injection nozzle 200 or the cylindrical structure according to the present invention. That is, when the liquid is introduced into the inlet port 221 by the air pressure, the inlet opening and closing means 230 moves the spring 240 in a direction in which the spring 240 is folded, The inlet 221 can be opened. Then, when the liquid is not introduced into the inlet 221, the spring 240 is restored and the inlet opening / closing means 230 blocks the inlet 221. To this end, the inlet opening and closing means 230 is preferably connected to the spring 240 or inserted into or contained therein, so that the inlet opening and closing means 230 moves together with the spring 240 as it is folded and restored. For example, the inlet opening / closing means 230 is provided in the longitudinal direction of the cylindrical structure 210 inside the cylindrical structure 210 and includes a head 231 corresponding to the inlet 221, 231, and a support 232 inserted into the spring 240.

In the present invention, the other side of the injection nozzle 200 or the cylindrical structure 210 has a collecting groove 212 and a whirlpool guide groove 213. It is preferable that the collecting groove 212 and the whirlpool guide groove 213 are formed on the outer side of the outer side of the injection nozzle 200 or the cylindrical structure 210. The collecting groove 212 and the whirlpool inducing groove 213 are grooves formed on the surface of the other side surface or a path made of such grooves and have a predetermined step difference from the surface of the other side surface, Through which liquid can be collected or moved. The collecting groove 212 collects the liquid discharged from the discharge port 211. A whirlpool guide groove 213 is formed between the discharge port 211 and the collecting groove 212. The liquid discharged from the discharge port 211 is collected in the collecting groove 212 after moving along the whirlpool guide groove 213.

The whirlpool guide groove 213 has two or more curved shapes connected to the collecting groove 212 from the discharge hole 211. That is, two or more curved paths connect the discharge port 211 and the collecting groove 212, respectively. Thus, the liquid discharged from the discharge port 211 may be divided into two or more curved paths and then collected in the collecting groove 212. Since the whirlpool induction groove 213 is formed in a curved shape, the liquid passing through the curved shape is primarily broken while rotating. Then, the water particles moved along the respective whirlpool guide grooves 213 are collected in the collecting grooves 212. As the water particles moved in different directions collide with each other in the collecting grooves 212, It becomes finer. In addition, the water particles moving along the curved path are rotated in one direction in the collecting groove 212 to form water trunks. The present invention has the effect of making the particle size of the liquid even smaller by making the liquid to be transported to be whirled through the whirlpool guide groove 213 and the collecting groove 212.

The injection cap 300 has an injection port 310 for injecting liquid to the outside at a position corresponding to the collecting groove 212. The injection cap 310 has an inner surface in which the other side of the cylindrical structure is closely adhered and inserted. That is, the injection cap 300 is installed in the injection nozzle 200 or the cylindrical shape 210 so that the inner surface of the injection cap 300 is closely contacted to the other outer side surface of the injection nozzle 200 or the cylindrical structure 210 according to the present invention. And a part of the other side of the structure 210 is wrapped. More specifically, the inner surface of the injection cap 300 is in close contact with the other outer surface of the cylindrical structure 210, and the whirlpool guide groove 213 and the collecting groove 212, which are formed on the other outer surface of the cylindrical structure 210, Through which the water particles can be made into smaller particles while bumping into the whirlpool guide groove 213 and the collecting groove 212 more quickly. The small water particles thus produced are ejected to the outside through the ejection port 310 formed at the position corresponding to the collecting groove 212.

According to the present invention, by making the particle size of the sprayed liquid (for example, hydrogen or sterilizing water) smaller, it is possible not only to increase the reactivity with the fine particles, but also to increase the water content It is possible to spray evenly, thereby further enhancing the sterilizing effect on the object and visually providing a fantastic spraying effect.

In addition, the present invention may have the following other features.

First, the support member 232 is preferably shorter than the spring 240. When the liquid is introduced into the inlet 221 by the air pressure, the spring 240 is folded by the force to open the inlet 221. When the length of the support 232 is longer than the spring 240, (240) is not folded so that it is difficult to open the inlet (221). Thus, the support 232 is preferably shorter than the spring 240, and more preferably 1/5 to 4/5 the length of the spring 240. If the length of the support 232 is too short, it may be disengaged from the spring 240, which is not suitable.

The collecting groove 212 according to the present invention is formed at the center of the other side of the injection nozzle 200 or the cylindrical structure 210 and the discharge port 211 is formed around the circumference of the collecting groove 212 desirable. Although the collecting groove 212 may be formed on the other side of the cylindrical structure 210, in order for the water particles moved along the two or more whirlpool guide grooves 213 to be collected in one place, Area. Accordingly, it is preferable that the discharge port 211 is located at the periphery of the collecting groove 212, for example, in the middle area or the outer area of the other side.

It is further preferable that the whirlpool guide groove 213 has a curved shape that narrows in the direction of the collecting groove 212. That is, the curved shape has a wide width at the discharge port 211 side and a tapered shape at which the width is gradually narrowed toward the collecting groove 212. In this way, more liquid can be introduced into the collecting groove 212 when the width is larger at the discharge port 211, and a larger whirlwind stream can be formed while increasing the moving speed of the liquid when the width is narrow toward the collecting groove 212.

The other side surface of the cylindrical structure 210 may have a backflow preventing tip 215 formed along the outermost circumference. That is, the other side surface of the cylindrical structure 210 has a rim of a shape extending along the periphery at the outermost end. The rim of such protruding shape prevents water from leaking out of the other side surface or flowing backward in the direction of the nozzle bushing 100. The backflow prevention tails 215 may be formed of an inner backflow preventing jaw 215a and an outer backflow preventing jaw 215b spaced from each other. That is, two counterflow preventing tails 215 may be provided on the inner side and the outer side with a center space apart from each other at predetermined intervals. It is possible to more effectively prevent water from leaking or flowing back through the two backflow preventing taps 215. In addition, the injection cap 300 according to the present invention has a backflow preventing coupling portion that is coupled between the inner backflow preventing jaw 215a and the outer backflow preventing jaw 215b on the inner surface where the other side of the tubular structure 210 closely contacts. The backflow preventing tilts 215 are more closely adhered to each other.

 The other side of the injection nozzle 200 or the cylindrical structure 210 according to the present invention may further include a flow guide groove 214 formed around the center (middle) region. The flow path guide groove 214 may be formed in a shape that surrounds an outer periphery of the other side of the water flow path including grooves formed on the other side surface. In other words, a collecting groove 212 is formed in the central region of the other side, a whirlpool guide groove 213 is formed in the outer middle region of the central region, and an outer peripheral region The flow guide groove 214 is formed. In other words, the whirlpool guide groove 213 according to the present invention is formed in the middle area outside the center area on the other side of the cylindrical structure 210, and the other side of the cylindrical structure 210 is formed in the middle area And the flow guide groove 214 is formed in the periphery of the flow guide groove 214. The whirlpool guide groove 213 can be connected to the collecting groove 212 from the discharge hole 211 through the flow guide groove 214. According to the present invention, the water particles discharged from the discharge port 211 can be decomposed into fine particles having a small size while moving along the flow path guide grooves 214. It is also possible to uniformly supply water particles to the plurality of the whirlpool guide grooves 213 by the flow guide grooves 214.

The discharge port 211 is preferably formed in a region of the flow guide groove 214 or at a boundary portion where the flow guide groove 214 and the whirlpool guide groove 213 are in contact with each other. When the discharge port 211 is formed in the flow path guide groove 214, water particles discharged from the discharge port 211 can be supplied to the flow path guide groove 214 more quickly. When the discharge port 211 is formed in the boundary portion between the flow path guide groove 214 and the whirlpool guide groove 213, a part of the water particles is supplied to the flow guide groove 214, (213), it is possible to more effectively produce the water stem vortex. Further, the discharge ports 211 may be one or more, and two or more discharge ports 211 may be formed at different positions.

It is preferable that the flow path guide groove 214 is formed in a deeper groove than the whirlpool guide groove 213 on the other side of the cylindrical structure 210. That is, the depth of the flow guide groove 214 is deeper than the depth of the whirlpool guide groove 213. According to this structure, a larger amount of water particles can be rotationally moved by the flow path guide grooves 214, and water particles can be supplied to two or more of the plurality of tornado guide grooves 213, Stems can be created more effectively.

The whirlpool guide groove 213 may have a bottom surface inclined toward the flow guide groove 214 at an end connected to the flow guide groove 214. That is, the bottom surface of the whirlpool guide groove 213 is inclined toward the channel guide groove 214, so that the flow of water from the channel guide groove 214 to the whirlpool guide groove 213 can be made more convenient have.

In addition, the flow path guide groove 214 may have a vertical side contacting the center region. That is, the inner side surface (side surface of the collecting groove 212) forming the flow path guide groove 214 is vertically formed. Of course, in this case, it is preferable that the connection portion with the whirlpool guide groove 213 is connected to the groove. In other words, if the inner side surface except for the connection portion with the whirl-inducing groove 213 is vertically formed, the water particles can be introduced more effectively by the desired connection portion alone.

It is preferable that three or more curved grooves having a predetermined radius of curvature are connected to the collecting grooves 212 from three or more different points of the flow path guide grooves 214 Do. In addition, the three or more different points may be positions symmetrical to each other about the collecting groove 212. Although the whirlpool induction groove 213 may be formed of two or more curved lines having different shapes, it is preferable that the whorl guide grooves 213 are arranged in a predetermined direction at different positions having the same curved shape, It is more effective because it can be made. It is preferable that the whirlpool guide groove 213 has three to seven curved shapes, more preferably five curved shapes.

In addition, in the present invention, the injection port 310 of the injection cap 300 may have a cross-sectional structure in which the inner surface of the injection cap 300 is wide and the outer surface is narrow. That is, the hole has a wide hole at the side of the collecting groove 212 and a hole narrowed at an inclined angle from the hole toward the outside of the injection cap 300. By further decomposing the water particles through such a tapered cross-section, it is possible to produce smaller size fine particles.

The injection cap 300 may be rotated to adjust the distance between the inner surface of the injection cap 300 and the other surface of the cylindrical structure 210 so that the injection port 310 of the injection cap 300 It is also possible to control the amount and intensity of the water particles ejected from the nozzle.

According to another aspect of the present invention, there is provided an injection device including the above injection module. Such an injector may be a conventional atomizer or spray gun, or may be an industrial oil injector or an automotive fuel injector.

Further, the present invention may further include a storage vessel (not shown) for storing water or sterilizing water to be delivered to the nozzle bushing 100 of the injection module. The shape, size, and structure of the storage container are not particularly limited.

Although the present invention has been shown and described with respect to certain preferred embodiments thereof, it will be understood by those skilled in the art that various changes in form and details may be made therein without departing from the spirit and scope of the invention as defined by the following claims It will be apparent to those skilled in the art.

1: Injection device
100: Nozzle Bushing
200: injection nozzle
210: cylindrical structure
211: Outlet
212: Collecting Home
213:
214: flow guide groove
215:
220: nozzle cap
221: inlet
230: inlet opening / closing means
231: Head
232: Support
240: spring
300: injection cap
310:

Claims (19)

A nozzle bushing for delivering the liquid by air pressure;
An inflow port formed at one side of the cylindrical structure and through which the liquid transferred from the nozzle bush is introduced; and an inflow port formed in the tubular structure by a spring, Wherein the tubular structure includes at least one inlet opening and closing means for opening and closing the tubular structure, and at least one outlet formed at the other side of the tubular structure for discharging liquid introduced through the inlet, And two or more curve-shaped whirl-inducing grooves connected to the collecting grooves from the discharge port, respectively; And
And an injection cap having an inner surface in which the other side of the cylindrical structure is closely adhered and inserted and having an ejection port for ejecting liquid to the outside at a position corresponding to the collection groove,
Wherein the other side surface of the cylindrical structure has a backflow preventing jaw formed along the outermost circumference, and the backflow preventing jaws include an inner backflow preventing jaw and an outer backflow preventing jaw that are spaced apart from each other.
The method according to claim 1,
The injection nozzle includes a cylindrical structure having the other side of the cylindrical structure, a nozzle cap inserted into one side of the cylindrical structure, the inlet opening / closing means provided in the cylindrical structure, and the inlet opening / And a spring.
3. The method of claim 2,
Wherein the inlet port is formed at one side of the nozzle cap,
Wherein the inlet opening and closing means is provided in the longitudinal direction of the cylindrical structure inside the cylindrical structure and comprises a head corresponding to the inlet and a support extending from the head and inserted into the spring.
The method of claim 3,
Wherein the support is shorter in length than the spring.
3. The method of claim 2,
Wherein the collecting groove is formed at the center of the other side of the cylindrical structure,
And the outlet is formed around the periphery of the collecting groove.
6. The method of claim 5,
Wherein the whirlpool inducing groove has a curved shape that narrows in the direction of the collecting groove.
delete delete A nozzle bushing for delivering the liquid by air pressure;
An inflow port formed at one side of the cylindrical structure and through which the liquid transferred from the nozzle bush is introduced; and an inflow port formed in the tubular structure by a spring, Wherein the tubular structure includes at least one inlet opening and closing means for opening and closing the tubular structure, and at least one outlet formed at the other side of the tubular structure for discharging liquid introduced through the inlet, And two or more curve-shaped whirl-inducing grooves connected to the collecting grooves from the discharge port, respectively; And
And an injection cap having an inner surface in which the other side of the cylindrical structure is closely adhered and inserted and having an ejection port for ejecting liquid to the outside at a position corresponding to the collection groove,
Wherein the collecting groove is formed at the center of the other side of the cylindrical structure, the discharge port is formed around the circumference of the collecting groove,
Wherein the whirlpool guide groove is formed in a central region including the center on the other side of the cylindrical structure,
The other side surface of the cylindrical structure further includes a flow guide groove formed around the center region,
Wherein three or more curved grooves having a predetermined radius of curvature are connected to the collecting grooves from three or more different points of the flow path guide grooves,
Wherein the discharge port is formed in the flow path guide groove region or at a boundary portion where the flow path guide groove region and the whirlpool guide groove are in contact with each other.
delete 10. The method of claim 9,
Wherein the flow guide groove is formed in a deeper groove than the whirl-inducing groove on the other side of the cylindrical structure.
12. The method of claim 11,
Wherein the whirlpool induction groove has a bottom surface inclined from an end of the flow guide groove to the flow guide groove.
13. The method of claim 12,
Wherein the channel guide groove has a vertical side in contact with the center region.
delete 10. The method of claim 9,
Wherein the three or more different points are symmetrical with respect to each other about the collecting groove.
10. The method of claim 1 or 9,
Wherein the jetting port of the jetting cap has a sectional structure in which the inner surface is wide and the outer surface is narrow.
10. The method of claim 1 or 9,
Lt; RTI ID = 0.0 > a < / RTI > liquid atomizer.
An injection device comprising an injection module according to any one of claims 1 to 9.
19. The method of claim 18,
Further comprising a storage container for storing water or sterilizing water to be delivered to the nozzle bushing of the injection module.

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