KR100984055B1 - A nozzle assembly for spraying mixed fluid - Google Patents

Abstract

PURPOSE: A nozzle assembly for spraying mixed fluid is provided to prevent misalignment of nozzles by integrating a nozzle support through an injection molding. CONSTITUTION: A first nozzle sprays first fluid. A second nozzle(300) discharges second fluid. Exhaust nozzles(210,310) are formed on the first nozzle and the second nozzle. A nozzle support(100) is integrated with the first and second nozzles. A cone shaped exhaust cap(400a,400b) forms the exhaust nozzle to spray and mix the first and second fluid.

Description

A nozzle assembly for spraying mixed fluid

The present invention relates to a nozzle assembly for a mixed fluid injection, and more particularly to a nozzle assembly for mixing and injecting two different types of fluid, a pair of nozzles for injecting two different types of fluid, respectively And, by integrally forming a nozzle support for fixing the pair of nozzles in the direction orthogonal to each other through injection molding is configured so that the pair of nozzles always maintain a constant alignment state, improving the injection efficiency of the mixed fluid The present invention relates to a nozzle assembly for mixing a mixed fluid.

In the modern industrial society, various air conditioning and heating equipment and devices have been developed to maintain indoor temperature and humidity suitable for human activities.As a result of this change in residential culture, people can live comfortably in the optimal living environment in their houses and apartments. It is running. However, in order to improve the efficiency of heating and cooling, occupants should cut off the flow of outdoor and indoor air. As a result, house dust that inhabits dead cells of humans is inhabited due to environmental conditions such as insufficient ventilation and relative humidity of more than 50%. The habitat of ticks will also maintain optimal conditions. These dust mites cause adults and children to cause allergies and respiratory diseases.

Such dust mites can be eliminated by using drugs or high-temperature sterilization, etc. One of the methods may be a steam sterilizer.

Typically, the steam sterilizer is provided with a reservoir for storing water and a reservoir for disinfecting liquid inside the sterilizer main body, and a heater assembly for heating water to a high temperature and a nozzle assembly for spraying water and disinfectant solution, the nozzle assembly The disinfectant solution discharged through the water is configured to be sprayed by mixing with the steam generated by heating the water to a high temperature.

Of these, the nozzle assembly constituting the steam sterilizer is fixed in a direction perpendicular to each other so that the ejection outlet of the first nozzle for ejecting steam through the nozzle support and the ejection outlet of the second nozzle for discharging the disinfecting solution are orthogonal to each other so that the disinfectant solution can be effectively sprayed. have.

However, such a nozzle assembly is usually configured to fix the first nozzle to one side of the body of the injection port, and to adjust the outlet of the second nozzle to be perpendicular to the nozzle of the first nozzle to be fixed to the nozzle body through the outer periphery of the nozzle. There is a difficulty in adjusting the alignment during assembly.

In particular, when the second nozzle is fixed to the nozzle body by using a fixing means such as a bolt, the second nozzle is released from the fixed position due to deterioration of the fixing means or the nozzle body in accordance with the long-term use of the steam sterilizer. There is a problem that the alignment state is shifted and the injection efficiency of the disinfectant solution may be lowered.

In addition, since the second nozzle is formed in a hollow cylindrical pipe shape, and is fixed in a state of being exposed to the inside of the injection hole, the disinfectant solution, which is not sprayed upon spraying the disinfectant solution using steam, flows along the outer circumferential surface of the second nozzle as it is. Lowering the injection efficiency is also lowered, there is also a problem that can contaminate the nozzle assembly.

The present invention has been made to solve the above problems, in configuring a nozzle assembly for mixing and injecting two different types of fluid, a pair of nozzles for injecting two different types of fluid, respectively, By integrally forming a nozzle support that fixes the pair of nozzles in a direction perpendicular to each other through injection molding, the pair of nozzles can be configured to maintain a constant alignment state at all times, thereby improving the injection efficiency of the mixed fluid. It is an object of the present invention to provide a nozzle assembly for spraying a mixed fluid.

The nozzle assembly for the mixed fluid spray according to the present invention includes a first nozzle for injecting a first fluid; A second nozzle for discharging a second fluid; A nozzle support for integrally coupling and fixing the first nozzle and the second nozzle so that the ejection holes formed in the first nozzle and the second nozzle are aligned in a direction perpendicular to each other; A cone coupled to the nozzle support to surround the first nozzle and the second nozzle, the cone forming an injection hole for mixing and spraying a first fluid and a second fluid injected through the first nozzle and the second nozzle ( The nozzle support is configured to include, and integrally formed through the injection molding and the first nozzle and the second nozzle, the outer peripheral surface of the first nozzle and the second nozzle, A plurality of fixing grooves are formed to be formed so that the raw material of the nozzle support is filled in the plurality of fixing grooves when injection molding with the nozzle support to secure the coupling between the nozzle support and the first nozzle and the second nozzle. It features.

According to the nozzle assembly for spraying mixed fluid according to the present invention, a pair of nozzles for injecting two different types of fluids and a nozzle support for fixing the pair of nozzles in a direction perpendicular to each other are integrally formed through injection molding. By forming, the pair of nozzles can be configured to always maintain a constant alignment state, there is an effect that can prevent the misalignment of the alignment state between the nozzles by long-term use.

In addition, in the case of the second nozzle for discharging the fluid in the liquid state of the pair of nozzles, a step is formed between the outer circumferential surface of the second nozzle and the nozzle support so that the fluid that is not sprayed by steam is continuously concentrated at the step and continuously. It is possible to increase the injection efficiency by being completely injected by the steam injected into the nozzle, it is also possible to prevent contamination of the nozzle assembly.

1 is an exploded perspective view showing the configuration of a nozzle assembly for a mixed fluid injection according to an embodiment of the present invention.
Figure 2 is a perspective view showing a combined state of the nozzle assembly for the mixed fluid spray shown in FIG.
3 is a cross-sectional view showing the internal configuration of the nozzle assembly for the mixed fluid spray shown in FIG.

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

First, the nozzle assembly for mixed fluid injection according to the present invention is connected to an injector for storing two different types of fluids, for example, water and a chemical liquid, so that one fluid, that is, water is sprayed in the form of high-pressure vaporized water vapor. And a nozzle assembly for injecting and mixing another fluid, that is, a chemical solution in a venturi manner.

1 is an exploded perspective view showing the configuration of the nozzle assembly for the mixed fluid injection according to an embodiment of the present invention, Figure 2 is a perspective view showing a combined state of the nozzle assembly for the mixed fluid injection shown in Figure 1, Figure 3 is 2 is a cross-sectional view showing the internal configuration of the nozzle assembly for the mixed fluid spray shown in FIG.

1 to 3, the nozzle assembly for the mixed fluid injection according to the present invention, the first nozzle 200 for injecting the first fluid, the second nozzle 300 for discharging the second fluid, and The first nozzle 200 and the second nozzle 300 are arranged such that the first nozzle 210 and the second nozzle 310 formed in the first nozzle 200 and the second nozzle 300 are aligned in a direction perpendicular to each other. It is coupled to the nozzle support 100 in the form of enclosing the nozzle support 100 and the nozzle support 100 to be integrally coupled and fixed to surround the first nozzle 200 and the second nozzle (300) It is configured to include a cone cap (400a, 400b) of the cone (cone) to be combined so that the injection nozzle is injected to the mixed fluid injected from the first nozzle 200 and the second nozzle (300).

In this case, as shown in the cross-sectional view of FIG. 3, the nozzle support 100 is integrally formed with the first nozzle 200 and the second nozzle 300 through injection molding. In this regard, the nozzle support 100 will be described later. It will be described in more detail through the specific description of the coupling relationship of the.

The first nozzle 200 may be made of a material such as metal, the outer shape is made of a cylindrical shape, there is formed a first fluid passage 214 penetrating the body in the longitudinal direction to move the first fluid therein. .

The first nozzle 200 is provided in the main body (not shown) of the injection apparatus and is connected to the first fluid storage container (not shown) for storing the first fluid by using a first pipe (not shown), and the first fluid storage container. The first fluid, for example water, contained in is heated to a high temperature and sprayed in the form of vaporized water vapor. As such, the first fluid injected through the first nozzle 200 needs to be injected in the form of vaporized water vapor and mixed with the second fluid discharged through the second nozzle 300 to be injected at a high pressure. For this purpose, the first fluid passage 214 is formed in the form of an orifice (orifice) narrowed in diameter toward the first outlet 210 from the first inlet 212, the first fluid is introduced through the first pipe It is preferable.

In addition, a filter 240 is formed at the first inlet 212 through which the first fluid flows to filter impurities contained in the first fluid flowing through the first pipe. As the filter 240, various kinds of filters may be used, and in the exemplary embodiment of the present invention, a sintered filter formed by pressing a fine bracket to a certain shape and heating it to a temperature close to the melting point of the bracket is used.

On the outer circumferential surface of the first nozzle 200, a plurality of first fixing grooves 220 of a predetermined depth are formed in order to secure the coupling with the nozzle support 100, and the first nozzle 200 applied to the present embodiment 1 Inlet 212 side outer circumferential surface is formed with a screw thread 230 for connecting to the main body of the injection device, the portion of the thread 230 is to start the elastic O-ring 250 is mounted to prevent fluid leakage do.

The second nozzle 300 may also be made of a material such as metal, and is made of a hollow cylindrical pipe shape, and a second fluid passage 314 penetrating the body in the longitudinal direction to move the second fluid is formed therein. have.

The second nozzle 300 is provided in a second fluid reservoir (not shown) which is provided in the main body of the injection apparatus and stores the second fluid through the second inlet 312 formed at one side of the second fluid passage 314. It is connected using two pipes (not shown), and discharges the second fluid in the liquid state through the second jet port 310 formed on the other side of the second fluid passage (314). At this time, the second jet port 310 of the second nozzle 300 is aligned in a direction orthogonal to each other with the first jet port 210 of the first nozzle 200, the second fluid is the first fluid of the vaporized water vapor type As the high pressure is injected to the outside through the first jet port 210, the pressure around the jet port is sharply lowered to be discharged to the outside through the venturi method through the second jet port (310).

In addition, a plurality of second fixing grooves 320 having a predetermined depth are formed on the outer circumferential surface of the second nozzle 300 to secure the coupling with the nozzle support 100.

 The nozzle support 100 includes a first nozzle such that the first nozzle 210 and the second nozzle 310 formed in the first nozzle 200 and the second nozzle 300 are aligned in a direction perpendicular to each other. It is formed by injection molding so that the 200 and the second nozzle 300 are integrally coupled and fixed. During injection molding of the nozzle support 100, the nozzle support material in a fluid state is formed into the first fixing groove 220 and the second fixing groove 320 formed on the outer circumferential surfaces of the first nozzle 200 and the second nozzle 300, respectively. After the injection molding, the nozzle support 100 is engaged with the first fixing groove 220 and the second fixing groove 320 respectively formed in the first nozzle 200 and the second nozzle 300 to be integrally fixed. As a result, the alignment between the first nozzle 200 and the second nozzle 300 can be prevented from being deteriorated due to deterioration due to prolonged use of the injection apparatus.

In addition, a portion of the nozzle support 100 to which the second nozzle 300 is fixed is formed to surround the outer circumferential surface of the second nozzle 300, wherein the second ejection opening 310 of the second nozzle 300 is the nozzle support. It is formed to be fixed and exposed to a predetermined length from the (100). Through such a configuration, a step 124 is formed between the outer peripheral surface of the second jet port 310 side of the second nozzle 300 and the nozzle support 100 so that the high pressure from the first jet port 210 of the first nozzle 200 is increased. By concentrating a second fluid that is not sprayed by the first fluid that is injected in the steam state to the step 124 secondary so that all can be injected by the first fluid continuously sprayed through the first jet port (210) It is possible to prevent the nozzle assembly from being contaminated by the fluid.

The nozzle caps 100a and the nozzle caps 400a and 400b are coupled to the nozzle support 100 so as to surround the first nozzle 200 and the second nozzle 300. For this purpose, the nozzle caps 100a and 400b of the nozzle support 100 are combined. The coupling surface to be coupled is formed with a guide groove 130 for facilitating the coupling, and a fastening hole 126 for fixing the injection port caps 400a and 400b is formed at a predetermined position of the nozzle support 100. have.

The nozzle caps 400a and 400b are coupled to the nozzle support 100 in a form surrounding the first nozzle 200 and the second nozzle 300, and are sprayed from the first nozzle 200 and the second nozzle 300. The first fluid and the second fluid to be mixed to form a spraying nozzle.

The injection hole caps 400a and 400b are formed in a hollow cone shape, and are cut in the longitudinal direction to facilitate engagement with the nozzle support 100 so as to be symmetrical with each other, such that the first injection hole cap 400a and the second injection hole cap ( 400b). A guide groove 130 formed in the nozzle support 100 so that the coupling surface coupled to the nozzle support 100 in the first injection hole cap 400a and the second injection hole cap 400b can be fitted with the guide groove 130. Guides 402 are formed respectively, and a guide or a guide groove is selectively formed on the coupling surface where the first injection hole cap 400a and the second injection hole cap 400b are coupled to each other. Can be.

In addition, a pair of first wings 410a and a second wing 410b protruding a predetermined length are formed at both edges of the first injection hole cap 400a and the second injection hole cap 400b, respectively. The first fixing hole 420a and the second fixing hole 420b penetrating the body are formed in the 410a and the second wing 410b, respectively. When fixing the first injection hole cap 400a and the second injection hole cap 400b to the nozzle support 100, as shown in FIG. 2, an upper portion of the first injection hole cap 400a and the second injection hole cap 400b is shown. The side is in the state in which the first injection port cap 400a and the second injection port cap 400b are in close contact with each other, and on the lower side, the nozzle support 100 is interposed between the first injection port cap 400a and the second injection port cap 400b. In one state to be able to be coupled using a fixing means 500, for example bolts. At this time, the fixing means 500 is inserted into the first fixing hole 420a and the second fixing hole 420b on the upper side of the first injection hole cap 400a and the second injection hole cap 400b, and the first injection hole cap 400 On the lower side of the 400a) and the second injection hole cap 400b, the fixing means 500 is inserted into the first fixing hole 420a, the fastening hole 126, and the second fixing hole 420b, and thus the first injection hole cap 400a. And the second injection hole cap 400b are fixed to the nozzle support 100.

As described above, the first nozzle 200 and the second nozzle 300 for injecting two different types of fluids, respectively, and the first nozzle 210 formed in the first nozzle 200 and the second nozzle 300, respectively. And the nozzle assembly 100 integrally formed by injection molding to integrally couple the first nozzle 200 and the second nozzle 300 so that the second ejection opening 310 is aligned in a direction perpendicular to each other. There is an advantage that it is possible to simplify the manufacturing process, and to prevent the nozzles from being misaligned due to deterioration due to prolonged use.

In addition, a step 124 is formed between the outer circumferential surface of the second nozzle 300 and the nozzle support 100 so that the second fluid discharged through the second nozzle 300 is injected at a high pressure from the first nozzle 200. The second fluid focused on the step 124 is continuously sprayed from the first nozzle 200 by being configured to be focused on the step 124 secondly even if it cannot be injected by the first fluid in the water vapor form. Since all can be injected to the outside by the one fluid, the injection efficiency can be improved and at the same time there is an advantage that the nozzle assembly 100 can be prevented from being contaminated.

The present invention described above is not limited to the above-described embodiments and the accompanying drawings, and various substitutions, modifications, and changes are possible in the art without departing from the technical spirit of the present invention. It will be clear to those of ordinary knowledge.

The mixed fluid spray nozzle assembly according to the present invention is applied to various spraying apparatuses or spraying apparatuses for injecting two different kinds of fluids, and can be used in service industries such as cleaning and disinfection or painting industry.

100 nozzle nozzle 124 step
200: first nozzle 210: first ejection outlet
212: first inlet 214: first fluid passage
220: first fixing groove 230: thread
240: filter 250: O-ring
300: second nozzle 310: second outlet
312: second inlet 314: second fluid passage
320: second fixing groove 400a: first injection nozzle cap
400b: second injection hole cap 410a: first wing
410b: the second wing 420a: the first fixed hole
420b: second fixing hole 500: fixing means

Claims (6)

A nozzle assembly for injecting two different types of fluids,
A first nozzle for injecting a first fluid;
A second nozzle for discharging a second fluid;
A nozzle support for integrally coupling and fixing the first nozzle and the second nozzle so that the ejection holes formed in the first nozzle and the second nozzle are aligned in a direction perpendicular to each other;
A cone coupled to the nozzle support to surround the first nozzle and the second nozzle, the cone forming an injection hole for mixing and spraying a first fluid and a second fluid injected through the first nozzle and the second nozzle ( nozzle cap of cone shape;
Consists of including
The nozzle support,
It is formed integrally by injection molding with the first nozzle and the second nozzle,
On the outer circumferential surface of the first nozzle and the second nozzle,
A plurality of fixing grooves are formed to be formed so that the raw material of the nozzle support is filled in the plurality of fixing grooves when injection molding with the nozzle support to secure the coupling between the nozzle support and the first nozzle and the second nozzle. The nozzle assembly for the mixed fluid injection, characterized in that. delete The method of claim 1,
The second nozzle,
And a stepped portion formed between the outer periphery of the jet port for discharging the second fluid and the nozzle support. The method of claim 1,
The first nozzle,
The nozzle assembly for the mixed fluid injection, characterized in that a sintered filter for filtering impurities contained in the first fluid is installed in the inlet for the first fluid. The method of claim 1,
The nozzle cap,
It is composed of a first injection port cap and a second injection port cap of the shape that is cut in the longitudinal direction corresponding to each other,
On the upper end side of the first injection port cap and the second injection port cap, one side surface of the first injection port cap and one side surface of the second injection port cap are coupled to each other, and at the lower end side of the first injection port cap and the second injection port cap The nozzle assembly for the mixed fluid injection, characterized in that the nozzle support is coupled between the first injection port cap and the second injection port cap. The method of claim 5, wherein
Guide grooves are formed on an engagement surface of the nozzle support body to which the nozzle support body is coupled to the first and second injection port caps.
Mixing fluid powder, characterized in that the guide corresponding to the guide groove is formed and fitted to each of the coupling surface of the first and second injection port cap coupled to the nozzle support is coupled to the first and second injection port cap Use nozzle assembly.

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