KR200341109Y1 - Nozzle assembly for fire extinguishing - Google Patents

Abstract

It is proposed a fire extinguishing nozzle assembly having a function of effectively extinguishing fire and preventing fire spreading, especially for an oil fire.

In the nozzle assembly for fire extinguishing according to the present invention, when the extinguishing liquid flows into the nozzle body from an external pipe and is ejected through the flow path inside the nozzle body, the extinguishing liquid passes through the gap formed between the flow path and the cone disposed in the flow path. I do it. This gap exerts an effect equivalent to the so-called nozzle throat and accelerates the extinguishing fluid. The accelerated extinguishing liquid also collides with the impingement plate formed at the tip of the cone so as to be located near the nozzle outlet, and becomes particulated and ejected.

Description

Fire Nozzle Assembly {NOZZLE ASSEMBLY FOR FIRE EXTINGUISHING}

The present invention relates to a fire extinguishing nozzle assembly for ejecting a liquid for use in a sprinkler or the like for fire extinguishing.

A fire extinguishing nozzle fixed to a ceiling of a building and the like has a function of diffusing a liquid into fine particles in order to spray and extinguish an extinguishing liquid (water or extinguishing liquid) effectively against a combustion product caused by a fire. As a method of diffusing this digestive liquid into particulate form, for example, 1) a method of adding a rotating component to the flow of the digestive liquid and diffusing and atomizing it by centrifugal force, 2) a method of ejecting the digestive liquid from a small slit, and 3) a flow of the digestive liquid And a method of colliding the flow of a plurality of extinguishing liquids have been conventionally used.

1 shows an example of a conventional sprinkler nozzle. This nozzle 1 consists of the frame 2, the connection part 3 with the piping which is not shown in figure, and the diffuser 4. As shown in FIG. When the nozzle 1 is used, the extinguishing liquid supplied from a pipe (not shown) is ejected from the discharge port 5, and the ejected liquid collides with the diffuser plate 4 to radiate the radius of the diffuser plate 4. Diffuses in the direction and becomes particulate.

In this nozzle 1, for example, when the pressure of the extinguishing liquid is 1 kg / cm ² and the flow rate is 80 L / min, the liquid atomized to a diameter of about 1 mm is injected. This corresponds to a fire such as wood (A fire).

In such a conventional fire extinguishing nozzle, since the diameter of the liquid fine particles generated is about 1 mm as mentioned above, especially in an oil fire, the cooling effect by latent heat of vaporization by the evaporation of a liquid is small, and the particle | grains in a fire generating part are small. Since the density was also small, the effects of extinguishing or suppressing combustion on flames or combustion gases were insufficient.

The present invention proposes a fire extinguishing nozzle assembly having a function of suppressing fire extinguishing and effective fire extinguishing for a fire, particularly an oil fire, in view of the problems of the conventional fire extinguishing nozzle.

That is, the nozzle assembly for fire extinguishing according to the present invention includes a nozzle body having a hollow flow path and a cone fixed inside the nozzle, and through the hollow flow path of the nozzle body, the cone and the cone Arranged so as to form a gap between the flow path inner wall, a collision plate having a planar shape in the shape of a disk and a radial cross-section having a sharp edge at the periphery is located near the outlet of the nozzle body. When the liquid is ejected from the nozzle body, the liquid is collided with the impingement plate to diffuse the liquid while making it particulate.

In the nozzle assembly for fire extinguishing according to the present invention, when the extinguishing liquid flows from the external pipe into the nozzle body and ejects through the flow path inside the nozzle body, the extinguishing liquid passes through the gap formed between the flow path and the cone disposed in the flow path. I do it. This gap exerts the same effect as the so-called nozzle throat and accelerates the extinguishing liquid. The accelerated extinguishing liquid also impinges on the impingement plate formed at the tip of the cone to be located near the nozzle outlet.

The impingement plate has a substantially disk-like planar shape, and has a radial cross-sectional shape where the periphery forms an acute angle, that is, a sharp knife edge shape. As a result, the extinguishing liquid impinging on the impingement plate diffuses into a thin film form and becomes fine particles, and is ejected from the nozzle outlet with a hollow cone-shaped spray pattern. At this time, the particle size of the fine particles of the digestion liquid is a size of several tens to several hundred micrometers. Therefore, the extinguishing liquid is easily evaporated in the combustion part due to the fire, and the cooling effect due to latent heat of vaporization due to the evaporation and the suffocation action by the generated steam are promoted, and the extinguishing liquid floating in the air in the fire generating part is promoted. The cooling effect of the absorption of heat due to collision of combustion residues in particulates and flames or soot in combustion gas, and the shielding effect of forming a spray pattern of fire extinguishing fluid are combined to effectively extinguish and burn. Can be suppressed.

1 is a view showing an example of a conventional fire nozzle, Figure 1a is a front view showing a part of the cross section, Figure 1b is a side view, Figure 1c is a plan view showing a diffusion plate,

Figure 2 is a view showing an embodiment of a nozzle nozzle for fire extinguishing according to the present invention, Figure 2a is a side view showing the left half in cross-section, Figure 2b is a plan view showing a spout,

3 is a longitudinal cross-sectional view showing a nozzle body of the nozzle nozzle for fire fighting shown in FIG. 2;

Figure 4 is a view showing a strainer of the nozzle nozzle for fire fighting shown in Figure 2, Figure 4a is a longitudinal cross-sectional view, Figure 4b is a cross-sectional view along the line A-A of Figure 4a,

5 is a view showing the cone of the nozzle nozzle for fire fighting shown in Figure 2, Figure 5a is a top view, Figure 5b is an external view, Figure 5c is an enlarged view of the impact plate of the tip,

FIG. 6 shows the fire extinguishing nozzle assembly shown in FIG. 2, FIGS. 6A and 6B show a mesh and FIG. 6C shows a mesh clamper.

Explanation of symbols for main parts of the drawings

1: nozzle 2: frame

3: connection part with piping 4: diffusion plate

5 outlet 10 nozzle assembly

11: nozzle body 12: strainer

13: cone 14: mesh

15 mesh clamper 28 collision plate

2 to 6 show an embodiment of a fire extinguishing nozzle assembly according to the present invention, FIG. 2 shows the entire assembly, and FIGS. 3 to 6 show its component parts, respectively.

The nozzle assembly 10 shown in FIG. 2 is composed of a nozzle body 11, a strainer 12, a cone 13, a mesh 14, and a mesh clamper 15. As shown in FIG. 3, the nozzle body 11 has a hollow shape in which a flow path 18 having an inlet 16 and an outlet 17 is formed, and the flow path 18 has a minimum cross section 19. To raise. In addition, the outer surface of the nozzle body 11 is provided with a thread 20 for attachment to a pipe or ceiling not shown, and in addition, a part of the inner wall of the threaded flow path 18 is provided with a strainer 12 as described later. ) To form a thread 21 for fixing. In addition, in this nozzle main body 11, as shown in figure, the shape of the flow path 18 is made into the taper nozzle type which internal diameter becomes small toward the minimum end surface part 19 for the reason mentioned later.

As shown in FIG. 4, the strainer 12 provides a flow path 23 having an outlet 22 therein and forms a plurality of inflow holes 24 in the side (eight in the figure). . Moreover, the screw hole 25 for fixing the mesh clamper 15 mentioned later is formed in the top part of the strainer 12. As shown in FIG. In the lower part of the strainer 12, the screw thread 20 formed in the nozzle body 11 mentioned above and the screw thread 26 for screwing together are formed.

The cone 13 consists of a cylindrical base 13a and an extension part 13b protruding downward from the base 13a toward the nozzle exit direction. A plurality of flow paths 27 (four in the figure) penetrating in the direction of the center axis of the cross section are provided, and a collision plate 28 is provided at the tip of the extension part 13b. In particular, as enlarged in FIG. 5C, the periphery of the impingement plate 28 has a sharp knife edge type. In addition, the diameter D1 of the impingement plate 28 is larger than the diameter D2 of the smallest diameter part of the extension part 13b, and the minimum cross-sectional part 19 of the flow path 18 of the said nozzle main body 11 is carried out. It is assumed to be equal to or slightly smaller than the diameter Da of. In addition, when the nozzle assembly 10 is assembled, the length of the cone 13 and the installation position inside the main body of the cone 13 are set so that the collision plate 28 does not protrude from the outlet 17. .

The mesh 14 is attached to surround the outer periphery of the strainer as shown in Fig. 2, and the plate-shaped material shown in Fig. 6A is rounded in a cylindrical shape as shown in Fig. 6B, and the spot welding 29 (Fig. 3 places). In addition, as shown in FIG. 6C, the mesh clamper 15 has a disk shape in which a hollow hole 30 is formed in the center.

Next, the assembly procedure of the nozzle assembly 10 is demonstrated. First, the cone 13 is inserted into the flow path 18 of the nozzle body 11. Further, the cylindrical mesh 14 is placed on the strainer 12, and the mesh clamper 15 is mounted on the top of the strainer 12, and then the screw s (see FIG. 2) is replaced with the hollow hole 30 and the screw hole. Inserted into 254, the mesh 14 is fixed. Finally, the strainer 12 is inserted into the flow path 18 to screw the threads 20 and 26 to fix the strainer 12 in the nozzle 11. In addition, as is apparent from FIG. 2B, the extinguishing liquid flows through the annular gap formed by the flow path 18 and the cone 13 of the nozzle body 11 to be ejected from the outlet 17.

Here, the operation of the nozzle assembly 10 will be described. First, a fire extinguishing liquid (for example, water) supplied from a pipe (not shown) flows through the mesh 14 from the inlet hole 24 of the strainer 12 into the internal flow path 23 and flows to the outlet port 22.

Subsequently, the extinguishing liquid passes through the flow path 27 of the cone 13 and flows through the gap between the flow path 18 inside the nozzle body 11 and the extension 13b of the cone 13. Here, the flow path 18 has a tapered nozzle shape in which the inner diameter becomes small toward the minimum end face 19, and in the minimum end face 19, since the cross-sectional area of the gap is the smallest, this part is a so-called nozzle throat. Is added. For this reason, the flow of the extinguishing liquid is accelerated by passing through this minimum end face portion 19.

The accelerated extinguishing fluid is ejected from the nozzle outlet 17, but at that time, the jet pattern on the hollow park is formed by flowing the annular gap formed by the flow path 18 of the nozzle body 11 and the cone 13. At the same time, they collide with the collision plate 28 of the cone 13. By colliding with the impingement plate 28, particularly the peripheral portion of the knife edge type, the extinguishing liquid becomes particulate and diffused.

When extinguishing liquid is injected from the nozzle assembly 10, the extinguishing liquid becomes fine particles having a diameter of several tens to several hundred micrometers. For example, when the pressure of the extinguishing liquid is 10 kg / cm ² and the flow rate is 20 L / min, the extinguishing liquid atomized into particles having a diameter of about 100 μm is injected. This is particularly effective against oil fires.

The nozzle assembly for fire extinguishing according to the present invention sprays the extinguishing liquid into finer particles than the conventional fire extinguishing nozzles, and therefore, more effectively extinguish the fire and suppress the combustion for fires in buildings, ships, and the like, especially oil fires. It is possible to plan.

Claims (1)

In a fire extinguishing nozzle assembly, A nozzle body having a hollow flow path, And a cone fixed inside the nozzle, The cone is arranged to pass through the hollow flow path of the nozzle body and to form a gap between the cone and the inner wall of the flow path, A collision plate having a planar shape in the shape of a disk and a radial cross-section having an acute edge at the periphery thereof is provided near the outlet of the nozzle body, When the liquid is ejected from the nozzle body, the liquid is collided with the impingement plate to diffuse the liquid while making it particulate. Fire extinguishing nozzle assembly.