RU172957U1 - Fire extinguisher nozzle - Google Patents

Abstract

Fire extinguisher nozzle containing first and second sleeves coaxially connected to each other. The first sleeve is made conical and is a nozzle with an internal through hole that extends along the entire sleeve by stepwise changing the diameter from larger to smaller and is made in the body of this sleeve so that four cylindrical regions and two conical are formed, and the region with a smaller diameter is a hole the outlet of the jet, and the region with the largest diameter contains a thread for connection to the second sleeve by means of an existing thread on its outer surface in the connection area, in addition, the second sleeve has holes made in the body of the sleeve so that it is possible to pass the flow of the extinguishing agent through a cylindrical section, first turning into a conical section, and then into a cylindrical one having vertically oriented holes for distributing the output of the stream of extinguishing agent into the cylindrical region of the first sleeve, this cylindrical the region of the first sleeve is the region that follows the region with the largest diameter. The technical result consists in the possibility of extinguishing electrical installations under voltage, by increasing the degree of crushing of the extinguishing agent at the outlet of the nozzle. 2 C.p. f-ly, 2 ill.

Description

Technical field

This utility model relates to fire extinguishing agents, in particular nozzles for spraying a fire extinguishing agent.

State of the art

There are various types of nozzles for spraying a fire extinguishing agent (see, for example, patent RU 2132752 C1, published July 10, 1999). In a known technical solution, a nozzle is used with which a long-range gas-droplet jet is generated. The liquid atomizer includes a profiled gas-dynamic nozzle, a liquid and gas mixing chamber, means for dispersing the liquid flow supplied to the mixing chamber, and a system for supplying liquid and gas to the mixing chamber. The extinguishing fluid in this device is stored in a container and is forced out of it during operation under the action of compressed gas pressure.

A distinctive feature of this analog nozzle is that, in an analog, the process of crushing a solid jet into a finely dispersed one occurs only in one plane — horizontal with the help of two rods arranged crosswise, which does not provide complete safety for the operator when extinguishing electrical installations under voltage, because any displacement of one of the rods in one direction or another or loss of the rod leads to the fact that the jet turns into a continuous one, and this, in turn, can lead to fatal consequences when extinguishing electrical equipment without turning off the power supply.

Consider the known device does not allow you to get a jet with fine droplets with a diameter of 100-150 microns due to its design.

Utility Model Disclosure

The purpose of this utility model is to obtain a spray jet consisting of fine droplets with a diameter of 100-150 microns from a stream of a continuous stream of extinguishing agent.

The technical result of the proposed utility model is the possibility of extinguishing electrical installations under voltage by increasing the degree of crushing of the extinguishing agent at the outlet of the nozzle.

The specified technical result is achieved by the fact that the nozzle of the fire extinguisher contains the first and second sleeves coaxially interconnected, the first sleeve being conical and is a nozzle with an internal through hole that runs along the entire sleeve by a stepwise change in diameter from larger to smaller and is made in the body of this sleeve so that four cylindrical regions and two conical regions are formed, the region with a smaller diameter being the outlet of the jet, and the region with the largest diameter it contains a thread for connection with the second sleeve by means of an existing thread on its outer surface in the connection area, in addition, the second sleeve has an inlet cylindrical cavity open to the flow of the extinguishing agent into it, which is made in the body of this sleeve and mates with an internal conical cavity, which in turn, is associated with an inner cylindrical section having openings for discharging a stream of extinguishing agent stream into the cylindrical region of the first sleeve, and this cylindrical region is not howl sleeve is a region that comes next after the region with the largest diameter of the first sleeve, in addition to the output openings of the jet of extinguishing agent flow in the first cylindrical region of the sleeve are oriented so that their axis of symmetry perpendicular to the axis of symmetry of the second sleeve.

In one embodiment of the claimed utility model, a gasket is provided in the threaded joint area.

In one embodiment of the claimed utility model, there is a thread on the outer surface of the second sleeve from the inlet side.

Brief Description of the Drawings

In FIG. 1 shows a general view of the nozzle.

In FIG. 2 shows a section of a nozzle.

Utility Model Implementation

According to figure 1, the nozzle of the fire extinguisher contains coaxially interconnected first (1) and second sleeves (2). The first sleeve is made conical (in particular, the surface of the first sleeve has a cylindrical section turning into a section, which is essentially a section made in the form of a truncated cone) and is a nozzle with an internal through hole (8), which runs along the entire sleeve by a stepwise change in diameter from larger to smaller, it is made in the body of this sleeve so that four cylindrical regions and two conical regions are formed (the conical regions are sections or regions made inside so that in the cross section they are truncated cones, smaller diameters of which, when viewed along the fluid flow, pass into cylindrical cavities), the region with the smaller diameter being the outlet of the jet (9), and the region with the largest diameter containing thread ( 4) for connection with the second sleeve by the existing thread on its outer surface in the connection area.

The second sleeve has an inlet cylindrical cavity (7) open for supplying a stream of extinguishing agent to it, which is made in the body of the sleeve and is associated with an internal conical cavity, which in turn is associated with a cylindrical section having vertically oriented holes (6) for outputting a stream of flow extinguishing agent into the cylindrical region of the first sleeve, the cylindrical region of the first sleeve being the region that goes next after the region with the largest diameter of the first sleeve .

The presented nozzle differs from others in that the process of breaking a solid jet occurs successively in three stages: in horizontal, vertical and again horizontal planes, which gives a 100% guarantee of obtaining a finely dispersed jet with a droplet size of up to 100 microns, thereby ensuring the safety of the operator when extinguishing live electrical installations.

As can be seen in FIGS. 1 and 2, vertical holes (6) for distributing the jet output are made in the body of the sleeve in the region of its cylindrical section, which, after connecting one sleeve to the other, by screwing them, is located in the area of the cylindrical section of the first sleeve. In this cylindrical section of the first sleeve, the initial stage of the formation of a finely dispersed stream of the jet is carried out. Next, the flow of the fragmented jet goes into the first conical section of the first sleeve, then into a cylindrical one with a smaller diameter, then into a conical and again into a cylindrical one, which is the outlet exit hole (9).

In the area of the threaded connection there is a sealing gasket (5).

From the inlet side (from the side of the open cylindrical cavity of the second sleeve), a thread (3) is applied on the outer surface of the sleeve.

In addition, the second sleeve (2) is a fitting containing on the outer surface an annular stop made of the material of this sleeve. This annular emphasis provides the possibility of a rigid and tight connection between the first and second sleeves, by a threaded connection. The edge of the first sleeve when screwing it onto a part of the second sleeve abuts against the ring stop (shoulder) indicated above.

The second sleeve (fitting) inside contains a cavity configured to direct the flow of extinguishing agent first through its cylindrical cavity, which then passes into a truncated conical section, which in turn passes into a cylindrical section. Moreover, in this cylindrical section (cylindrical cavity) made in the body of the sleeve and passing along the axis of symmetry of the second sleeve, holes are made, the axis of symmetry of which are perpendicular to the longitudinal axis of symmetry of the second sleeve.

The main objective of the nozzle is to break a continuous stream of extinguishing agent stream into a sprayed stream consisting of fine droplets with a diameter of 100-150 microns.

Also, this design of the spray nozzle compares favorably with the known models in that, due to the proximity of the nozzle opening to the differential angle of the spray nozzle (cascade of angles), an intensified pressure extinguishing agent (OTV) is created in a finely dispersed form, which makes it possible to obtain an OTV jet length of up to 12 meters and gives the ability to extinguish electrical equipment with guarantee without shutting off the power supply.

The signs characterizing the presence of a connection between the sleeves, the presence of cavities with alternating conical and cylindrical sections in the first sleeve, the presence of an input cylindrical region in the second sleeve for directing the stream of the stream to vertically oriented holes, as well as the presence of sealing and thrust elements (creating a sealed connection to create high pressure conditions, which affects the formation of a finely dispersed jet), is at cause and effect connection with the above result, namely, aimed at extinguishing electrical installations under voltage, by increasing the degree of crushing of the extinguishing agent at the outlet of the nozzle.

Claims (3)

1. The nozzle of the fire extinguisher, containing the first and second sleeves coaxially connected to each other, characterized in that the first sleeve is conical and is a nozzle with an internal through hole that runs along the entire sleeve by a stepwise change in diameter from larger to smaller and is made in the body of this the sleeves so that four cylindrical regions and two conical regions are formed, the region with the smaller diameter being the outlet of the jet, and the region with the largest diameter containing threads for connection about the second sleeve by means of an existing thread on its outer surface in the connection region, in addition, the second sleeve has an inlet cylindrical cavity open for supplying a stream of extinguishing agent into it, which is made in the body of the liner and is associated with an internal conical cavity, which in turn is paired with a cylindrical a section having openings for discharging a stream of extinguishing medium into the cylindrical region of the first sleeve, and this cylindrical region of the first sleeve is an area that the next after the region with the largest diameter of the first sleeve, in addition, the openings for discharging a stream of extinguishing medium into the cylindrical region of the first sleeve are oriented so that their axis of symmetry is perpendicular to the axis of symmetry of the second sleeve. 2. The nozzle of the fire extinguisher according to claim 1, characterized in that in the area of the threaded connection there is a sealing gasket. 3. The nozzle of the fire extinguisher according to claim 1, characterized in that there is a thread on the outer surface of the second sleeve from the inlet side.

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