RU2846955C1 - Pyrotechnic flare for localization of forest fires - Google Patents

Abstract

FIELD: fire-fighting means.

SUBSTANCE: invention relates to fire-fighting equipment, namely to a pyrotechnic flare for localization of forest fires. Pyrotechnical flare for localization of forest fires is equipped with igniter initiated by external electric pulse, comprises cylindrical body with holes for outlet of flame force, in which pyroelement is coaxially placed. Peculiar feature is that pyroelement consists of pyrotechnic composition pressed through cardboard layer into metal cup with hole, on which a rolled paper tube is installed, forming a receiver between the pyroelement and the neck of the cylindrical housing with holes providing a degree of diaphragming of the combustion surface of the pyroelement in range of 6-12, wherein the volume of receiver is 0.3-0.5 of the internal volume of the cylindrical housing, and the pyroelement is further provided with reinforcing layers of an igniting pyrotechnic composition and an axial channel in which an igniting agent is placed at a depth of not less than 1/4 of the height of the pyroelement, and the channel diameter is 0.1-0.2 of the pyroelement diameter, which from the end surface is covered by the metal wire mesh, and from the bottom is fixed by the damping gaskets and covered by the heat-shielding material in the form of a circle with a hole, through which the igniting means wires are brought out, wherein the pyroelement is waterproofed from atmospheric moisture by epoxy resin filling the gap between the hole in the circle and the igniter wires, as well as by the metal foil covering the holes in the neck of the cylindrical housing.

EFFECT: expansion of an arsenal of devices for fire suppression on large areas, and also expansion of their functional and technological resources at their production.

1 cl, 1 dwg

Description

The invention relates to fire-fighting equipment, namely to devices for containing fires over large areas, in particular forested areas.

Combating forest fires is one of the most important tasks of Russian forestry. More than 90% of forest fires are surface fires. Crown and peat fires also start from surface fires. Therefore, the development of new technologies for extinguishing and containing surface fires of varying intensity improves the effectiveness of forest protection systems and is therefore highly relevant.

The most effective methods for creating artificial firebreaks include mineralized strips, firebreaks and barriers, fire-resistant edges, fire ditches, and firebreak and support strips. Support strips are created in the forest during the fight against an existing forest fire.

The level of this field of technology is characterized by a fire extinguishing means according to patent RU 2242259, A62C 3/02 from 03.07.2003, which includes a container with a fire extinguishing composition and a dispersing charge, a detonating device and a stabilizer, and it is equipped with a suspension system located on the outer surface of the container symmetrically to a plane passing through the center of mass of the means and made in the form of two hoops, spaced apart and rigidly connected by a plate with ears, while the container and stabilizer are made of a thermoplastic polymer material.

A drawback of the known device is that while the spherical liquid spray effectively extinguishes crown fires, 10 minutes after extinguishment, re-ignitions quickly occur across 70-90% of the temporarily extinguished area. This necessitates multiple sorties for repeated firefighting bombing of localized areas of forest fires or requires immediate response from firefighting crews after aerial firefighting.

A method for extinguishing forest fires is known according to patent RU 2492888, A62C 3/02 dated 09.21.2011, which, based on its technical essence and the number of matching features, was chosen as the closest analogue to the proposed invention.

The essence of this method is the formation of an artificial line of oncoming fire front by exposing a helicopter to a mixture of fuel and air, supplied through hoses connected to a mixer under the helicopter at a safe distance to form a directed torch.

In addition, the mixer is equipped with additional removable metal discs to ensure minimal torch swing amplitude.

An artificial counter-fire line (ignition) is created by igniting a fuel-air mixture delivered from a helicopter ahead of the fire front at a distance determined by wind speed. The vertical movement of hot air masses creates a vacuum between the fronts. This condition causes them to move in opposite directions. The two fire fronts meet, burning out everything between them, and the fire is extinguished.

However, along with the effectiveness of fire localization by counter-burning, this method has a number of significant disadvantages.

To implement the known method, expensive logistical support is required: a helicopter, hoses over 20 m long, a mixer to form a torch, and metal disks.

In addition, a significant amount of fuel is required to operate the helicopter and create a fire front.

It should also be noted that maintenance and operation of a helicopter requires qualified personnel, an equipped helipad, etc.

Modern small unmanned aerial vehicles (UAVs) require no special maintenance or landing pads and are operated by a single person. These vehicles are ideal for delivering devices to create controlled fires in forested areas.

The technical result of the claimed invention is the expansion of the arsenal of devices for containing fires over large areas, as well as the expansion of their functional and technological capabilities in their production.

The technical problem that the present invention is aimed at solving is to increase the efficiency for the intended purpose and reduce labor and resource costs when extinguishing forest fires by backburning.

The required technical result is achieved in that the pyrotechnic torch for localizing forest fires, equipped with an igniter initiated by an external electrical impulse, contains a cylindrical body with openings for the flame nozzle outlet, in which a pyroelement is coaxially placed.

The peculiarity of the proposed technical solution is that the pyroelement consists of a pyrotechnic composition pressed through a layer of cardboard into a metal cup with an opening, onto which a paper-rolled tube is installed, forming a receiver between the pyroelement and the neck of a cylindrical body with openings that provide a degree of diaphragm of the combustion surface of the pyroelement in the range of 6-12, while the volume of the receiver is 0.3-0.5 of the internal volume of the cylindrical body, and the pyroelement is additionally equipped with reinforcing layers of igniter pyrotechnic composition and an axial channel in which the igniter is placed to a depth of at least ¼ of the height of the pyroelement, and the diameter of the channel is 0.1-0.2 of the diameter of the pyroelement, which is covered with a metal wire mesh from the end surface, and from the bottom part is fixed with a damping gasket and covered with heat-protective material in the form of a circle with an opening through which the wires are brought out igniter, while the pyroelectric element is waterproofed from atmospheric moisture by epoxy resin filling the gap between the hole in the circle and the wires of the igniter, as well as by metal foil covering the holes in the neck of the cylindrical body.

The pyrotechnic flare's geometric cylindrical shape allows it to be easily attached to a UAV using straps or clamps.

A pyrotechnic element made from a pyrotechnic composition has a significant advantage over its prototype due to the fact that the pyrotechnic composition is essentially a substance that, when burned, produces high-temperature combustion products, but this reaction does not require fuel or equipment for its dispersion.

Pressing a pyrotechnic composition through a layer of cardboard into a metal cup with a hole is a technologically advanced and safe operation for mass production.

The paper-rolled tube forms the receiver between the pyroelectric element and the neck of the cylindrical body with holes, the volume of which is 0.3-0.5 of the internal volume of the cylindrical body.

If the receiver volume is less than 0.3 of the internal volume of the cylindrical body, a sharp jump in internal pressure occurs when the torch is initiated, which can lead to dismantling and an unsteady combustion mode.

If the receiver volume is more than 0.5 of the internal volume of the cylindrical body, the mass of the pyrotechnic composition will be reduced, and, consequently, the overall burning time of the torch will be reduced.

The openings in the neck of the cylindrical body provide a degree of diaphragm for the combustion surface of the pyroelectric element in the range of 6-12, which ensures the equalization of internal pressure during the diffusion of combustion products, preventing the movement of the torch on the ground and simultaneously forming an intense stream of flame.

If the degree of diaphragm is less than 6, the holes in the neck of the cylindrical body become clogged with slag from the combustion products of the pyrotechnic composition, increasing the pressure inside the body, which leads to the appearance of jet thrust and involuntary movement of the torch on the ground.

When the degree of diaphragm is more than 12, the excess pressure in the housing becomes insufficient to form an intense flame jet.

Reinforcing layers of igniting pyrotechnic composition multiply the active combustion surface of the pyroelement, which is aimed at the almost instantaneous formation of a flame thrust.

The installation of an igniter in the pyroelement channel at a depth of at least ¼ of its height ensures stable ignition of the pyrotechnic composition by a distributed heat flow over the entire developed surface of the channel.

If the diameter of the pyroelectric element channel is less than 0.1 of its total diameter, the combustion surface is insufficient to quickly reach the efficient operating mode of the torch.

If the diameter of the pyroelement channel is more than 0.2 of its total diameter, the mass of the pyrotechnic composition will be reduced, and, consequently, the total burning time of the torch will be reduced.

The flow of burning particles, moving along the pyrotechnic element channel, is reflected from the complex surface of the metal mesh and increases the degree of impact of combustion products, ensuring reliable ignition of the pyrotechnic composition.

The damping gasket under the pyroelectric element serves to fill the technological gap and provides elastic support for the pyroelectric element without play in the cylindrical body.

Making a circle with a hole covering the bottom of the pyrotechnic element from a heat-protective material prevents flame from passing through the bottom of the pyrotechnic torch and, accordingly, dismantling the housing during operation.

Waterproofing of the pyrotechnic torch's internal volume is ensured by metal foil covering the openings in the neck of the cylindrical body and epoxy resin filling the gap between the opening in the circle and the ignition wires, which guarantees the pyrotechnic element's operational condition during long-term storage of the pyrotechnic torch, regardless of atmospheric conditions.

The pyrotechnic torch according to the proposed invention is an effective means of creating controlled fire sources on the ground in order to create a counter-burn for localizing fires in forest areas.

Using a pyrotechnic flare as a payload for a UAV significantly reduces the amount of logistics required to extinguish forest fires using artificial firebreaks.

The proposed pyrotechnic torch for localizing forest fires is characterized by a reliable design, a high mass flow rate of the composition, a rapid transition to an intensive combustion mode, and the use of progressive and safe technology for organizing large-scale production of products.

The essence of the proposed technical solution is illustrated by a drawing (Fig. 1), which is purely illustrative and does not limit the scope of the claims. The drawing depicts the proposed pyrotechnic torch.

A pyroelement (2) consisting of a pyrotechnic composition (3) with reinforcing layers of an igniter composition (4) pressed through a layer of cardboard (5) into a metal cup with an opening (6) is installed in the cylindrical body (1). An igniter (7) is installed in the central channel of the pyroelement (2).

A paper-rolled tube (8) is installed between the pyroelectric element (2) and the neck of the cylindrical body.

The pyroelectric element (2) is covered with a metal wire mesh (9) on the end surface, and is secured with a damping gasket (10) on the bottom and covered with heat-protective material in the form of a circle with an opening (11) through which the wires of the ignition agent (V) are led out.

Epoxy resin (12) fills the gap between the hole in the circle (11) and the ignition wires (7).

The holes in the neck of the cylindrical body (1) are sealed with metal foil (13).

The pyrotechnic torch functions as follows.

To activate the pyrotechnic torch, it is necessary to connect the bare ends of the ignition wires (7) to the terminals of a power source, for example, a UAV battery, and supply electric current to the circuit.

The igniter (4) transmits the fire impulse through the channel of the pyroelement (2), while the reinforcing layers of the igniter pyrotechnic composition (4) reliably activate the main pyrotechnic composition (3) of the pyroelement (2).

A flow of high-temperature products containing a gas and condensed phase, in the generator mode under pressure, flows out in the form of a flame jet through openings in the neck of the cylindrical body (1).

The flame force burns through the pyrotechnic torch's mount to the UAV, and it lands on the ground under its own weight.

Testing of prototypes of the proposed pyrotechnic flare confirmed the reliability of its operation in the established modes and sequence of actions when dropped from an unmanned aerial vehicle.

A comparative analysis of the proposed technical solution with identified prior art analogs, from which the invention does not clearly follow for a fire safety specialist, showed that it is unknown, and taking into account the possibility of practical serial production of a pyrotechnic torch in an existing production facility, it can be concluded that it meets the patentability criteria.

Claims (1)

A pyrotechnic torch for localizing forest fires, equipped with an igniter initiated by an external electrical impulse, comprising a cylindrical body with openings for the flame nozzle outlet, in which a pyroelement is coaxially placed, characterized in that the pyroelement consists of a pyrotechnic composition pressed through a layer of cardboard into a metal cup with an opening, on which a paper-rolled tube is installed, forming a receiver between the pyroelement and the neck of the cylindrical body with openings that provide a degree of diaphragm of the combustion surface of the pyroelement in the range of 6-12, wherein the volume of the receiver is 0.3-0.5 of the internal volume of the cylindrical body, and the pyroelement is additionally equipped with reinforcing layers of igniter pyrotechnic composition and an axial channel in which the igniter is placed to a depth of at least 1/4 of the height of the pyroelement, and the diameter of the channel is 0.1-0.2 of the diameter of the pyroelement, which with The end surface is covered with a metal wire mesh, and from the bottom it is fixed with damping gaskets and covered with heat-protective material in the form of a circle with a hole through which the wires of the igniter are brought out, while the pyroelement is waterproofed from atmospheric moisture with epoxy resin, filling the gap between the hole in the circle and the wires of the igniter, as well as with metal foil, covering the holes in the neck of the cylindrical body.