RU202065U1 - SPRINKLER SPRAYER - Google Patents

Abstract

The utility model is intended for automatic fire protection of objects extended along the length with the additional possibility of remote starting. Due to the presence of three rows of holes inclined to the central axis of the sprayer, made within the sector 100 °, the sprayer provides the formation, after triggering, of three fan-directed concentrically arranged torches of different dispersion over the protected zone extended along the length. The sprinkler nozzle has the ability to automatically trigger in the event of an ambient temperature exceeding the nominal temperature of the glass thermo-bulb and has the ability to trigger regardless of the ambient temperature by a remote command.

Description

A utility model designed for automatic fire protection of objects extended along the length with the possibility of its accelerated start-up, performed remotely, using a combined effect on the center of a forming torch, consisting of droplets with high kinetic energy, and a torch of rapidly cooling finely sprayed water located under the forming torch.

The known method of sprinkler fire extinguishing and a device for its implementation (3. No. 2019137052).

The known device is taken as a prototype and is a sprinkler spray containing a hollow cylindrical body with an internal chamber, with a valve located in it, made with the possibility of translational movement, a thermal lock in the form of a glass thermo flask and connected to the valve, nozzles are made located in the wall of the body and connected to the inner working chamber, the body is made in the form of a threaded pipe turning into a rim, the rim passes into a truncated cone, an opening is made on the upper part of the cone with a valve end located in it, on which one end of a glass thermo-bulb is installed, the other end of which is mated with the apex formed at the junction of the arches extending from the base of the cone, while at its end within a sector with an angle of 100 °, facing its apex to the plane in which the arches are located, three rows of holes inclined to the central axis of the atomizer are made in the wall of the cone, and in the first row of holes located at the base of the cone, the slope of the holes to the central axis of the atomizer is the greatest, in the third row of holes located at the top of the cone, the slope of the holes is the smallest, while the diameter of the holes of the third row is made the largest, with the possibility of forming a coarse droplet torch (the arithmetic mean diameter of the drops 150 μm), the diameter of the holes of the second row is made the smallest, with the possibility of forming a torch of finely sprayed water (the arithmetic mean diameter of the droplets is less than 100 μm), all holes are brought out into the inner chamber.

Automatic triggering of the prototype is carried out when the temperature of the controlled environment on the protected object rises above the nominal response temperature of the destructible glass thermo-bulb of the atomizer and does not provide for forced start-up of the atomizer, which could be carried out at an earlier stage of fire development.

The task of the utility model is to expand the functionality of the sprinkler nozzle, namely: the presence of an additional possibility of starting it at an early stage of fire development, in conditions when the temperature of the controlled environment has not yet reached the nominal response temperature of the thermo bulb.

The technical result should be: automatic triggering of the sprinkler spray by automatically destroying the glass thermo bulb, in case the ambient temperature at the protected object exceeds the nominal response temperature of the glass thermo bulb, and the possibility of forced start-up of the sprinkler nozzle regardless of the ambient temperature by a remote command.

This goal is achieved by the implementation of a sprinkler spray containing a hollow cylindrical body with an internal chamber, with a valve located in it, made with the possibility of translational movement, a thermal lock in the form of a glass thermo flask and connected to the valve is made, nozzles are made, located in the wall of the body and connected to the inner a working chamber, the body is made in the form of a threaded branch pipe, turning into a rim, according to the utility model, it passes into a truncated cone, on the upper part of the cone there is a hole with a valve end located in it, on which one end of a glass thermo bulb is installed, the other end of which is mated with the top, formed at the junction of the arches extending from the base of the cone, while in the wall of the cone within a sector with an angle of 100 ° facing its top to the plane in which the arches are located, there are three rows of holes inclined to the central axis of the atomizer, and in the first row of holes , located at the base of the cone, the slope of the holes to the central axis of the atomizer is greatest, in the third row of holes located at the top of the cone, the slope of the holes is the smallest, while the diameter of the holes in the third row is the largest, with the possibility of forming a coarse droplet plume (arithmetic mean diameter of droplets is 150 μm ), the diameter of the holes of the second row is made the smallest, with the possibility of forming a torch of finely sprayed water (the arithmetic mean diameter of the droplets is less than 100 microns), all holes are brought out into the inner chamber, according to the utility model, an electrically controlled forced start device is installed on the arms of the upper part of the atomizer.

The forced start device can be made in the form of a flexible figured strip, covering the arms of the atomizer, fixed on the arms with the help of the internal stops of the strip and with the help of a snap lock made at the ends of the strip, while on the wall of the strip there is a socket for a pyrotechnic drive, which is installed and fixed in the nest with a retaining ring, in the places of the strip bending, thinning is made and the possibility of connecting the pyrotechnic drive to the remote control circuit is provided.

The implementation of the spray gun is explained in more detail using the illustrations in FIG. 1, fig. 2, fig. 3.

FIG. 1 is a general view of the sprayer from below in the loaded state.

FIG. 2 is a general view of the bracket before installation on the sprayer.

FIG. 3 - General view of the sprayer on the right in section in the loaded state.

The device consists of a sprinkler nozzle 1 with a glass thermo bulb 2, a plastic bracket 3 with a pyrotechnic drive 4 installed on it, which is fixed with a retaining ring 5, while the bracket in its initial state is a plastic figured strip having at the ends mating parts 6 during assembly, 7 of a snap lock, having a hole 8 for installing a pyrotechnic drive, having two thinning 9 made at the bending points of the bracket, while in the assembled state the plastic figured strip covers the arms 10 of the sprayer, and the mating parts 6, 7 snap into place.

The device works as follows. Upon receipt of the electrical command "Start" supplied to the pyrotechnic drive 4, an immediate explosion of the pyrotechnic cartridge occurs and a shock wave of powder gases and decaying parts of the drive occurs, which leads to the destruction of the glass thermo-bulb 2, causes a tensile force along the entire bracket 3, which leads to the opening of parts 6, 7 of the lock, and the bracket 3 and the decaying parts of the drive are reset, the thermal lock of the sprinkler sprayer, further ensuring the regular operation of the sprayer, which is characterized by the creation of three fan-directed and concentrically formed extinguishing torches using holes 11, 12, 13.

Based on the foregoing, it can be seen that the installed electrically controlled forced start device, made in the form of a flexible strip, covering the arms of the atomizer and fixed on them with a latch, and the implementation of an electrically controlled pyrotechnic drive as part of the strip allow the destruction of the glass thermo bulb by a command received remotely, regardless of on the ambient temperature, expanding the functionality of the known atomizer, and the additional functionality does not limit the functionality of the atomizer inherent in the prototype.

Claims (2)

1. A sprinkler nozzle containing a hollow cylindrical body with an internal chamber with a valve located in it, made with the possibility of translational movement, a thermal lock in the form of a glass thermo-flask is made, connected to the valve, nozzles are made, located in the body wall and connected to the inner working chamber, the body is made in the form of a threaded pipe, turning into a rim, characterized in that the rim passes into a truncated cone, an opening is made on the upper part of the cone with a valve end located in it, on which one end of a glass thermo-bulb is installed, the other end of which is mated with a top formed at the junction of the arches extending from the base of the cone, while in the wall of the cone within a sector with an angle of 100 °, facing its top to the plane in which the arches are located, three rows of holes inclined to the central axis of the atomizer are made, and in the first row of holes, located at the base of the cone, the bosom of the holes to the central axis of the atomizer is the largest, in the third row of holes located at the apex of the cone the slope of the holes is made the smallest, while the diameter of the holes of the third row is made the largest, with the possibility of forming a large-droplet torch (the arithmetic mean diameter of droplets is 150 μm), the diameter of the holes of the second row is made the smallest one, with the possibility of forming a torch of finely sprayed water (arithmetic mean diameter of droplets 100 microns), all holes are brought out into the inner chamber, according to the utility model, an electrically controlled forced start device is installed on the arms of the upper part of the sprayer. 2. The sprinkler spray according to claim 1, characterized in that the forced start device can be made in the form of a flexible figured strip, covering the arms of the spray, fixed on the arms with a snap lock made at the ends of the strip, while on the strip wall there is a slot for of the pyrotechnic drive, which is installed and fixed in the socket with a retaining ring, thinning is made at the bend of the strip and the possibility of connecting the pyrotechnic drive to the remote control circuit is provided.

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