KR102106417B1 - Nozzle Vane for Automatic Fire Extinguisher - Google Patents

Abstract

The present invention relates to a nozzle vane (nozzle vane) mounted inside the nozzle (33) of the automatic fire extinguisher, mounted on the discharge passage of the fire extinguishing agent inside the nozzle (33), the upper portion of the medicine tank (11) of the automatic fire extinguisher A pointed tip portion 211 is formed toward the discharge tube 22 connected to, and a circular edge 212 is formed at the bottom portion, and a downward slope is formed at a side surface between the tip portion 211 and the edge 212. A vane body 210 having a plurality of induction curved portions 213 cut to form a concave curved surface in a clockwise or counterclockwise direction while forming; And a guide vane 220 protruding to form a concave curved surface in the opposite direction to the induction curved portion 213 while forming a downward slope on the surface of the induction curved portion 213 of the vane body 210. In addition, the end surface of the guide vane 220 is mounted to be in close contact with the inner surface of the fire extinguishing agent discharge passage inside the nozzle 33, thereby reducing frictional force during press fitting assembly work, and the fire extinguishing agent is the induction curved portion 213 and the It is guided along the guide vane 220 and then passes through the empty space between the guide vanes 220 and is ejected to the outside of the nozzle 33. It is characterized by.

Description

Nozzle Vane for Automatic Fire Extinguisher

The present invention relates to a structure of a nozzle vane mounted inside the nozzle 33 of an automatic fire extinguisher, and a vane body 210 having a plurality of induction curved portions 213 cut to form a concave curved surface while forming a downward slope ), And a guide vane 220 protruding to form a concave curved surface in a clockwise or counterclockwise direction while forming a downward inclination on the surface of the induction curved surface portion 213 of the vane body 210 through the nozzle 33 It characterized in that the downward rotational force (directionality) is given to the extinguishing agent ejected by.

In general, when a fire occurs due to a gas stove used in a kitchen or a kitchen, the fire detection sensor detects and supplies the fire extinguishing agent to an automatic fire extinguisher nozzle. The nozzle supplied with the extinguishing agent extinguish the fire by passing the extinguishing agent through the nozzle vane installed inside and spraying the fired gas stove. Here, the structure of the nozzle vane 5 inserted into the nozzle 10 for a conventional automatic fire extinguisher is as shown in Fig. 1 (a), the nozzle vane body 1 and the slope is opposite to each other, the upper and lower surfaces It consists of a spray diffusion unit (2) (3), each of which is provided with a hole (2a) (3a) to communicate.

However, in the conventional configuration as described above, as shown in FIG. There was considerable difficulty.

In addition, due to the phenomenon that the fire extinguishing agent is eccentric to one side when passing through the nozzle van, when the fire site where the fire extinguishing agent passes through the nozzle van is sprayed, it is not evenly distributed in a circular shape as a whole, and the fire extinguishing agent is concentrated only in a few fire parts There was a problem that was sprayed.

[Advanced technical literature]

Registered Patent No. 10-1118991

Registered Patent No. 10-1048029

Utility Model Registration No. 20-0452147

Registration No. 20-0420209

The present invention, created to solve the above problems, aims to provide a nozzle vane having a new structure capable of effectively extinguishing a fire by extinguishing the fire extinguishing agent evenly over the entire injection area.

The technical configuration of the present invention created to achieve the above object is as follows.

The present invention relates to a nozzle vane (nozzle vane) mounted inside the nozzle (33) of the automatic fire extinguisher, mounted on the discharge passage of the fire extinguishing agent inside the nozzle (33), the upper portion of the medicine tank (11) of the automatic fire extinguisher A pointed tip portion 211 is formed toward the discharge tube 22 connected to, and a circular edge 212 is formed at the bottom portion, and a downward slope is formed at a side surface between the tip portion 211 and the edge 212. A vane body 210 having a plurality of induction curved portions 213 cut to form a concave curved surface in a clockwise or counterclockwise direction while forming; And a guide vane 220 protruding to form a concave curved surface in the opposite direction to the induction curved portion 213 while forming a downward slope on the surface of the induction curved portion 213 of the vane body 210. In addition, the end surface of the guide vane 220 is mounted to be in close contact with the inner surface of the fire extinguishing agent discharge passage inside the nozzle 33, thereby reducing frictional force during press fitting assembly work, and the fire extinguishing agent is the induction curved portion 213 and the It is guided along the guide vane 220 and then passes through the empty space between the guide vanes 220 and is ejected to the outside of the nozzle 33. It is characterized by.

Technical effects according to the configuration of the present invention are as follows.

First, the sprayed fire extinguishing agent is ejected so as to have a certain directionality by the guide vane 220 and the guide curved portion 213 of the vane body 210, so that it can rotate downward and spread evenly throughout the injection area.

In other words, the guide curved portion 213 of the vane body 210 forms a concave curved surface in a clockwise or counterclockwise direction while forming a downward slope, and the guide vane 220 is concave in the opposite direction to the guide curved portion 213 Since the curved surface is formed, the extinguishing agent discharged through the discharge tube 22 is guided along the surfaces of the guide curved portion 213 and the guide vane 220 and finally discharged through the nozzle 33 to the outside. It has an effect of spreading evenly over the entire spraying area by being given a directionality that rotates downward in a clockwise or counterclockwise direction.

Second, by minimizing the discharge resistance in the process of imparting directionality to the extinguishing agent, the extinguishing agent is quickly discharged and efficient fire extinguishing is possible.

In other words, a large number of circular depressions 230 are formed on the surface in contact with the fire extinguishing agent, such that the resistance and friction noise are reduced, as is the dimple of the golf ball, so that the fire extinguishing agent can be discharged more smoothly.

Third, when the nozzle vane 200 is mounted inside the nozzle 33, the portion directly in contact with the inner surface of the nozzle is relatively small, so it can be more conveniently mounted.

In other words, unlike the prior art shown in FIG. 1 or 2, an empty space exists between the guide vanes 220 directly contacting the inner surface of the nozzle 33, so that the area directly contacting the inner surface of the nozzle 33 is relatively reduced. As the friction force is reduced to an appropriate range, the press fitting assembly can be performed more easily.

Fourth, since there is an empty space between the guide vanes 220, the cross-sectional area through which the fire extinguishing agent passes can be sufficiently secured so that the fire extinguishing agent can be ejected (sprayed) more smoothly.

Figure 1 shows the prior art.
2 shows the overall structure of an automatic fire extinguisher to which the present invention is applied.
3 is a specific embodiment of the present invention, showing the structure of the nozzle vane 200 mounted inside the nozzle 33.
Figure 4 is another specific embodiment of the nozzle vane 200 according to the present invention, (a) when the guide pin 221 is provided, (b) is shown a guide groove 222, respectively.
5 is another specific embodiment of the nozzle vane 200 according to the present invention, and shows a case in which a plurality of circular depressions 230 are provided.

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

As to a nozzle vane (nozzle vane) mounted inside the nozzle 33 of the automatic fire extinguisher,

2, the nozzle vane 200 of the present invention is a nozzle 33 mounted at the ends of the medicine tank 11, the discharge tube 22 connected to the medicine tank 11 and the discharge tube 22, as shown in FIG. ) Is installed inside the nozzle (33) of the automatic fire extinguisher, which is configured to impart directionality (downward rotational force) to the fire extinguishing agent to spread the fire extinguishing agent evenly over the entire spraying area.

Of course, a control-related device that automatically operates a fire extinguishing agent by a sensor should also be included. In general, a commercially available control-related device can be applied, and a detailed illustration or description is omitted because it is not directly related to the present invention.

The nozzle vane 200 mounted on the fire extinguishing agent discharge passage inside the nozzle 33 is composed of a vane body 210 and a guide vane 220 as shown in FIG. 3.

The vane body 210 is formed with a sharp tip portion 211 toward the discharge tube 22 connected to the medicine tank 11 of the automatic fire extinguisher at the upper end, and the cross-sectional area gradually increases toward the lower portion, thereby forming a circular border 212 at the lower portion. Is a structure that is formed.

Although not separately illustrated in the accompanying drawings, the overall shape of the border 212 is not necessarily limited to a circular shape, and may be a straight line or other curved shape.

The vane body 210 is not simply a conical structure, and the side between the tip 211 and the border 212 is cut to form a concave curved surface while inclining downward in the counterclockwise direction as shown in FIG. 3. A plurality of induction curved portions 213 are formed.

The induction curved portion 213 of the vane body 210 may form a downward curved surface in a counterclockwise direction, as shown in FIG. 3, or may be formed in a clockwise downward curved surface, although not separately illustrated in the accompanying drawings, or simply in a vertical direction. It can also form a downward curved surface.

The fire extinguishing agent discharged through the discharge passage inside the nozzle 33 follows the geometrical shape of the induction curved portion 213 and naturally meets the guide vane 220 to have a directionality.

The guide vane 220 protrudes to form a concave curved surface in the clockwise direction as shown in FIG. 3 while forming a downward slope on the surface of the induction curved portion 213 of the vane body 210. Of course, although not separately illustrated in the accompanying drawings, it may protrude to form a concave curved surface in a counterclockwise direction, such as the guide curved portion 213.

That is, the induction curved portion 213 of the vane body 210 forms a concave curved surface while forming a downward slope, and the guide vane 220 forms a concave curved surface in a clockwise or counterclockwise direction while forming a downward slope, discharged. The extinguishing agent discharged through the tube 22 naturally flows along the surfaces of the induction curved portion 213 and the guide vane 220, and finally discharged to the outside through the nozzle 33 to finally clockwise or counterclockwise. It is spread evenly over the entire spraying area by being given directionality that rotates downward in the direction.

The end surface of the guide vane 220 is mounted to be in close contact with the inner surface of the extinguishing agent discharge passage inside the nozzle 33, and the extinguishing agent is ejected out of the nozzle 33 by passing through the empty space between the guide vanes 220. .

That is, as shown in FIG. 3, the four guide vanes 220 protrude to maintain the same distance. An empty space exists between the guide vanes 220 and the extinguishing agent is discharged to the outside of the nozzle 33 through the empty space. It is an erupting structure.

In other words, as the area directly contacting the inner surface of the nozzle 33 increases, more force is required for assembling in a press-fitting (forcing fit) method, unlike the prior art shown in FIGS. 1 and 2. Since there are relatively few areas that directly contact the inner surface of the, assembly can be performed more easily.

The specific number of guide vanes 220 is not limited to four, but may be manufactured in a form in which two or three are provided, or may be in a form in which four or more are provided.

Figure 4 is another specific embodiment of the present invention, Figure 4 (a) shows a case where the guide pin 221 is provided, and Figure 4 (b) shows a case where the guide groove 222 is provided, respectively. .

In the case of FIG. 4 (a), guide pins 221 of a type in which the height gradually protrudes from the top to the bottom in the circumferential direction along the concave curved surface of the guide vane 220 are provided to improve the directionality of the extinguishing agent. It can be given more strongly.

In the case of Figure 4 (b), the guide groove 222 is recessed in the form of gradually increasing incision depth from the top to the bottom in the circumferential direction along the concave curved surface of the guide vane 220 is provided to the fire extinguishing agent Directionality may be imparted more strongly. In the case of FIG. 4 (b), the cross-sectional area of the fire extinguishing agent is increased compared to FIG. 4 (a).

5 is a partially enlarged view showing a case in which a plurality of circular depressions 230 are formed on the surface of the vane body 210 and the surface of the guide vane 220. As such, the circular depression is in contact with the extinguishing agent. When a plurality of parts 230 are formed, like the dimple of a golf ball, resistance and friction noise are reduced, so that the digestive fluid can be discharged more smoothly.

As described above, specific embodiments of the present invention have been described with reference to the accompanying drawings, but the protection scope of the present invention is not necessarily limited to these embodiments, and various design changes are within the scope of not changing the technical gist of the present invention. Even in the case of addition or deletion of known technology, simple numerical limitation, etc., it is apparent that it falls within the protection scope of the present invention.

11: Medicine tank
22: discharge tube
It is a nozzle 33
200: Nozzle vane
210: vane body
211: tip
212: Border
213: guide surface
220: Guide vanes
221: guide fin
222: guide groove
230: circular depression

Claims (4)

As to a nozzle vane (nozzle vane) mounted inside the nozzle 33 of the automatic fire extinguisher,
It is mounted on the discharge passage of the fire extinguishing agent inside the nozzle 33, and a sharp tip 211 is formed at the upper end toward the discharge tube 22 connected to the medicine tank 11 of the automatic fire extinguisher, and a circular edge is formed at the lower end. A 212 is formed, and a plurality of guide curved portions 213 cut off to form a concave curved surface in a clockwise or counterclockwise direction while forming a downward slope on the side surface between the tip portion 211 and the rim 212. Formed vane body 210; And,
A guide vane 220 protruding to form a concave curved surface in a direction opposite to the induction curved portion 213 while forming a downward slope on the surface of the induction curved portion 213 of the vane body 210;
It comprises,
The end surface of the guide vane 220 is mounted to be in close contact with the inner surface of the fire extinguishing agent inside the nozzle 33, thereby reducing friction during press fitting assembly, and the fire extinguishing agent is the induction curved portion 213 and the guide vane. It is guided along (220) and passes through the empty space between the guide vanes (220) and is ejected to the outside of the nozzle (33). Nozzle vane for automatic fire extinguisher. In claim 1,
A guide pin 221 protruding in a circumferential direction on the concave curved surface of the guide vane 220;
The nozzle vane for an automatic fire extinguisher, characterized in that it is provided in a form in which the height gradually protruding from the top to the bottom increases. In claim 1,
A guide groove 222 recessed in a circumferential direction on the concave curved surface of the guide vane 220;
The nozzle vane for an automatic fire extinguisher, characterized in that it is provided in a form in which the incision depth is gradually increased from the top to the bottom. In any one of claims 1 to 3,
A nozzle vane for an automatic fire extinguisher, characterized in that a plurality of circular depressions (230) are formed on the surface of the vane body (210) and the surface of the guide vane (220).

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