RU2259855C1 - Fire-extinguishing method and multijet fire-extinguishing powder flow forming device for above method implementation (variants) - Google Patents

Abstract

FIELD: fire-fighting equipment, particularly adapted to deliver fire-extinguishing material.

SUBSTANCE: method involves forming at least one set of gas-and-powder jets directed to fire site, wherein axes of adjacent jets in each set are directed at equal angles one relative another. The angle does not exceed half of jet spray angle. Three embodiments of gas-and-powder flow forming device are also disclosed.

EFFECT: increased fire-extinguishing reliability due to provision of high uniformity of specific fire-extinguishing powder discharge over the full surface to be protected.

12 cl, 7 dwg

Description

The invention relates to fire fighting equipment, and more particularly to methods and devices for extinguishing a fire with powder compositions.

The prior art method for extinguishing a fire, comprising the formation of at least one group of jets of a gas-powder mixture directed at a fire source (see international application WO No. 03824 A1, 1968). To implement this method, a multi-jet extinguishing powder flow former (described in the same place) is used, containing an inlet pipe with a nozzle located at its end, made in the form of splitters (blades) of a triangular gas-powder mixture flow, installed symmetrically relative to the longitudinal plane of symmetry of the inlet pipe.

A disadvantage of the known technical solution is that it does not provide high fire extinguishing due to the uneven distribution of the concentration of the extinguishing powder over the cross section of the gas-powder stream directly in the fire source. In other words, due to the axial symmetry of the nozzle, the thickness of the layer of extinguishing powder applied to the surface to be protected is not uniform.

There is also a known method of extinguishing a fire, taken as a prototype and involving the formation of at least one group of jets of a gas-powder mixture directed parallel to each other, while in each group of jets the gas supports of the bulk mixture are arranged with the same pitch around the central jet powder mixture (see copyright certificate SU No. 1706649 A1, 1992). The known method is implemented using the described there and taken as a prototype of a multi-jet former of a stream of fire extinguishing powder containing an inlet pipe, which is made in the form of a conical nozzle and is equipped with a nozzle coaxially mounted at its end. The nozzle is made in the form of a disk with channels having a funnel shape, tapering in the direction of flow of the extinguishing powder, one of the channels being aligned with the nozzle, and the rest with the same pitch around it around the circumference. The walls of each peripheral channel on the inner side of the disk are trapezoidal, and the central channel has the surface shape of a truncated pyramid with the number of side faces equal to the number of peripheral channels.

The disadvantage of the technical solution, taken as a prototype, is that when it is used, fire extinguishing over a large area is provided due to a significant increase in the specific consumption of extinguishing powder. Indeed, the surface area protected by one group of jets of the gas-powder mixture (in other words, one multi-jet former of the extinguishing powder flow) has a shape close to round, and its size is determined, firstly, by the dimensions in terms of the multi-jet former of the flow of extinguishing powder, and secondly , the opening angle of the jets of extinguishing powder. However, due to the near-circular shape of the surface portion protected by one multi-jet former of the extinguishing powder flow, it is not possible with the help of several multi-jet former of the extinguishing powder flow located at the same pitch relative to each other over the entire protected surface of a large area to ensure high fire extinguishing without significant mutual overlapping adjacent areas protected by respective multi-jet former current extinguishing powder. But a significant mutual overlap of separate, adjacent protected areas, having a shape that is close to round, leads, firstly, to a significant increase in the specific consumption of extinguishing powder compared to that necessary to eliminate this type of fire, and secondly, to the need to increase the number used multi-jet formers extinguishing agent flow.

The present invention is aimed at solving the technical problem of providing an increase in the area of the surface area protected by one group of jets of the gas-powder mixture (one multi-jet former of the extinguishing powder stream), while ensuring high uniformity of the concentration of extinguishing powder over the cross section of the flow of the gas-powder mixture near the protected surface area (directly in the focus fire), as well as increasing the efficiency of fire fighting. The technical result achieved in this case is to reduce the number of multi-jet formers of the extinguishing powder stream used to protect large areas, as well as to ensure high uniformity of the specific consumption of extinguishing powder throughout the entire surface to be protected due to the possibility of “joining” between each other with a minimum mutual overlap located separate protected by appropriate multi-jet shapers sections having a shape close to rectangular.

The problem is solved in that in a method of extinguishing a fire, comprising the formation of at least one group of jets of a gas-powder mixture directed to a fire source according to the invention each, a group is formed in the form of a beam of jets of a gas-powder mixture directed to a fire source, with each axis beam adjacent jets are placed at the same angle relative to each other, which does not exceed half the opening angle of the jets of the gas-powder mixture.

According to the first embodiment of the invention, from the point of view of the device, the problem is solved in that in a multi-jet former of the extinguishing powder stream containing an inlet nozzle with a nozzle at its end, according to the invention, the nozzle is made in the form of a bundle of nozzles whose axes are located in the same plane with the axis of the inlet nozzle and at the same angle relative to each other, which does not exceed half the opening angle of the jets of the gas-powder mixture.

In addition, the task is solved by the fact that

- the axis of all nozzle nozzles intersect at one point located on the axis of the inlet nozzle;

- nozzle nozzles are made of cylindrical shape and have the same shape and cross-sectional area;

- nozzle nozzles have either a rectangular cross-sectional shape, or round, or oval, or elliptical cross-sectional shape.

According to the second embodiment, the problem is solved in that in a multi-jet former of the extinguishing powder stream containing an inlet nozzle with a nozzle coaxially located at its end, according to the invention, the nozzle is made in the form of a bundle of an even number of nozzles, the axes of which are located at corresponding acute angles to a plane perpendicular to the axis of the inlet pipe, and intersect it at points corresponding to the nodes of a flat rectangular lattice, which is symmetrical with respect to two about perpendicular axes of symmetry of the second order parallel to the corresponding orthogonally located rows of nodal points of a flat rectangular lattice and intersecting at a point on the axis of the inlet pipe, while the axis of the pipes in each group of pipes, the axes of which are located in the corresponding plane crossing the plane perpendicular to the axis of the input pipe , along a line located along a number of nodal points of a flat rectangular lattice corresponding to this group of nozzles, are located at the same angle to each other relative to a friend who does not exceed half the aperture angle of the gas-powder mixture.

In addition tog, the task is solved by the fact that

- the intersection point of the axes of symmetry of the second order coincides with the intersection point of the diagonals of the central cell of a flat rectangular lattice;

- the middle row of nodal points of a flat rectangular lattice is located along one second-order symmetry axis;

- the axis of all nozzle nozzles intersect at one point located on the axis of the inlet nozzle;

- nozzle nozzles are made of cylindrical shape and have the same shape and cross-sectional area;

- nozzle nozzles have a rectangular cross-sectional shape;

- nozzle nozzles have a square cross-sectional shape;

- nozzle nozzles have either round, or oval, or elliptical cross-sectional shape;

- nozzle nozzles have a cross-sectional shape in the form of a regular polygon with more than four sides.

According to the third embodiment, the problem is solved in that in a multi-jet former of the extinguishing powder stream containing an inlet pipe with a nozzle coaxially located at its end, including a central nozzle and peripheral nozzles, according to the invention, the central nozzle is made in the form of a central pipe located coaxially with the inlet pipe, and peripheral nozzles - in the form of a bundle of an even number of peripheral nozzles, the axes of which are located at corresponding sharp angles to a plane perpendicular to the axis of the inlet pipe, the axes of the central and peripheral pipes intersect the above plane at points corresponding to the nodes of a flat rectangular lattice, which is symmetrical with respect to two mutually perpendicular symmetry axes of the second order lying along the first and second orthogonally located rows of nodal points of the flat rectangular lattice and intersecting at a point on the axis of the central nozzle, while the axis of the nozzles in each group of peripheral nozzles, axis k which are located in the corresponding plane intersecting the plane perpendicular to the axis of the inlet pipe, along a line located along a series of nodal points of a flat rectangular lattice corresponding to this group of peripheral pipes, it is located at the same angle relative to each other, which does not exceed half the opening angle of the gas-powder mixture.

In addition, the task is solved by the fact that

- the axis of all peripheral pipes intersect at one point located on the axis of the inlet pipe;

- all nozzle nozzles are cylindrical in shape and have the same shape and cross-sectional area;

- all nozzle nozzles have a rectangular cross-sectional shape;

- all nozzle nozzles have a square cross-sectional shape;

- all nozzle nozzles are either round, or oval, or elliptical in cross section;

- all nozzle nozzles have a cross-sectional shape in the form of a regular polygon with more than four sides.

The advantage of the proposed technical solution over the well-known (taken as a prototype) is that due to the formation of each group of jets of the gas-powder mixture directed to the fire source in the form of a beam in which the axes of adjacent jets are positioned at the same angle relative to each other, not exceeding half the opening angle of the jets of the gas-powder mixture, not only an increase in the area of the surface area protected by one group of jets of the gas-powder mixture is ensured, but also a uniform distribution of of the extinguishing powder concentration over the cross section of the gas-powder mixture flow directly in the fire area.

Indeed, due to the above mutual arrangement of the axes of adjacent fire extinguishing powder jets after their peripheral zones are mutually overlapped (which occurs at a certain distance from the multi-jet former of the fire extinguishing powder flow, depending on the angle between the axes of adjacent jets and the angle of their aperture) there is a gradual equalization of the concentration distribution of the extinguishing powder over the cross section of the flow of the gas-powder mixture. Thus, in a certain range of distances from the multi-jet former of the extinguishing powder stream, a uniform distribution of the extinguishing powder concentration over the cross section of the gas-powder mixture flow is ensured, and therefore, the same specific consumption of the extinguishing powder within the protected area. The specific consumption rate of the extinguishing powder is selected based on a predetermined specific consumption rate of the extinguishing powder, which provides reliable fire extinguishing of this class. In addition, when using the invention, increasing the efficiency of fire extinguishing is ensured by exposing the flame to a stream of a gas-powder mixture directed at an acute angle to the surface to be protected.

The proposed (according to the first, second and third embodiments of the multi-jet former of the extinguishing powder flow) arrangement of the axes of the nozzles, as well as their number, provides, firstly, an increase in the area of the surface area protected by one multi-jet former of the flow of extinguishing powder, without a significant increase in its size nozzles, and secondly, the rectangular shape of the protected area. The latter circumstance allows the “docking” between each other located separate protected areas with minimal mutual overlap and ensuring uniform distribution of the specific consumption of extinguishing powder within the entire protected surface.

The remaining signs relate to particular cases of the arrangement of second-order symmetry axes relative to the rows of nodal points of a flat rectangular lattice, particular cases of nozzles: nozzles, and also the preferred mutual arrangement of the axes of the nozzles, which simplifies the design of the shaper.

The present invention is illustrated by specific examples which, however, are not the only possible, but clearly demonstrate the ability to achieve the above set of essential features of the required technical result.

1 schematically depicts a multi-jet former of the flow of fire extinguishing powder, side view, according to the first embodiment of the invention; figure 2 is a cross section of the bundle of pipes with a plane perpendicular to the axis of the inlet pipe; figure 3 - the relative position in the space of the axes of the beam of the nozzles shown in figure 2; figure 4 and figure 5 - multi-jet formers flow extinguishing powder, General view, according to the second variant embodiment of the invention; figure 6 is the same according to the third variant embodiment of the invention, a partial section; Fig.7 - overlapping jets of gas-powder mixtures adjacent to the multi-jet formers flow extinguishing powder.

The multi-jet former of the extinguishing powder stream contains an inlet pipe 1 and a nozzle, which is located at the end of the inlet pipe 1 and is made in the form of a bundle of an even or odd number of pipes, for example, seven: P ₁ ÷ P ₇ (Fig. 1). The axis C ₁ -C _7, respectively, of the nozzles P ₁ ÷ P ₇ are located in the same plane (the plane of the drawing of FIG. 1) and at the same angle φ relative to each other, while the angle does not exceed half the angle α of the aperture of the jet - P of the gas-powder mixture exiting from each pipe P ₁ ÷ P ₇ , (figure 1 shows the jets emerging from the pipes P ₃ and P ₄ ). The axis 2 of the inlet pipe 1 lies in the same plane as the axis C ₁ ÷ C _{7 of the} pipes P ₁ ÷ P ₇ .

According to the second embodiment of the multi-jet former of the extinguishing powder flow, the nozzle is also located at the end of the inlet pipe 1 coaxially to its axis 2 and is made in the form of a bundle of even N × M numbers (where N and M are positive integers) of the pipes P ₁₁ , P ₁₂ , P ₁₃ , ..., P _1n , ..., P _1N ; P ₂₁ , P ₂₂ , P ₂₃ , ..., P _2n , ..., P _2N ; ...; P _m1 , P _m2 , P _m3 , ..., P _mn , ..., P _mN ; ...; P _M1 , P _M2 , P _M3 , ..., P _Mm , ..., P _MN , while in the cross section perpendicular to the axis 2 of the inlet pipe 1 (drawing plane of FIG. 2), the above beam pipes are located similarly to rectangular elements matrix (figure 2 and 3), and the axis C ₁₁ ÷ C _1N ; C ₂₁ ÷ C _2N ; ...; C _m1 ÷ C _mN ; ...; C _M1 ÷ C _MN , corresponding to the above nozzles P ₁₁ ÷ P _1N ; P ₂₁ ÷ P _2N ; ...; P _m1 ÷ P _mN ; P _M1 ÷ P _MN intersect the plane perpendicular to the axis 2 of the inlet pipe, at points T ₁₁ , T ₁₂ , T ₁₃ , ..., T _1n , ..., T _1N ; T ₂₁ , T ₂₂ , T ₂₃ , ..., T _2n , ... T _2N ; ...; T _m1 , T _m2 , T _m3 , ..., T _mn , ..., T _mN ; T _M1 , T _M2 , T _M3 , ..., T _Mn , ..., T _MN , which correspond to the nodes of a flat rectangular lattice (in the drawings shown in the form of two sets of dashed lines orthogonally relative to each other), which is symmetrical with respect to lying in that plane are two mutually perpendicular axes of symmetry 3 and 4 of the second order. Axes 4 and 3 are parallel to the orthogonally arranged rows (T ₁₁ ÷ T _1N ; ...; T _M1 ÷ T _MN ) and (T ₁₁ ÷ T _M1 ; ...; T _1N ÷ T _MN ) of the nodal points of the above flat rectangular lattices and intersect at a point located on axis 2.

Axis C ₁₁ ÷ C _1N ; C ₂₁ ÷ C _2N ; ...; With _M1 ÷ C, _MN are located at the corresponding acute angles ψ ₁₁ ÷ ψ _1N ; ...; ψ _M1 ÷ ψ _MN to a plane perpendicular to axis 2. In Fig. 3, this plane is indicated by 5. The axis of each of the above nozzles P ₁₁ ÷ P _MN is the intersection line of two planes, each of which intersects a plane perpendicular to axis 2, at a line located along the corresponding row of nodal points of a flat rectangular lattice. So (Fig. 3), the axis C _{mn of the} nozzle P _mn (not shown in Fig. 3) is the intersection line of plane 6 and plane 7. Plane 6 intersects plane 5, perpendicular to axis 2, along line 8 located along a number of nodal points of a flat rectangular lattices that correspond to the points T _m1 ÷ T _{mN of} intersection, respectively, of the axes C _m1 ÷ C _{mN of} one group of nozzles P _m1 ÷ P _mN with plane 5. Plane 7 intersects plane 5 along line 9 located along a number of nodal points of a flat rectangular lattice that correspond to the intersection points T _1n ÷ T _Mn, respectively but the axes C _1n ÷ C _{Mn of} another group of nozzles Р _1n ÷ Р _Mn with a plane 5. The axis of the nozzles in each group of nozzles indicated above (that is, nozzles whose axes are located in the corresponding plane intersecting plane 5, perpendicular to axis 2, along the line located along a number of nodal points of a flat rectangular lattice, which correspond to the intersection points of the axes of this group of nozzles with a plane 5) are located at the same angle φ relative to each other, which does not exceed half the opening angle α of the jets of the gas-powder mixture.

The intersection point of the second-order axes of symmetry 3 and 4 of the flat rectangular lattice coincides with the intersection point of the diagonals 10 (Fig. 4) of the central (closest to axis 2) cell of the flat rectangular lattice in the case when M and N are even numbers (Figs. 3 and 4 ), for example, M = 2, N = 6 of Fig. 4 (where also the pipes P ₁₁ ÷ P ₁₆ ; P ₂₁ ÷ P ₂₆ with the corresponding axes C ₁₁ ÷ C ₁₆ ; C ₂₁ ÷ C ₂₆ crossing the plane perpendicular to the axis 2, respectively, at the points: T ₁₁ ÷ T ₁₆ and T ₂₁ ÷ T ₂₆ ). In the case when M or N is an odd number (for example, M = 2, and N = 5 of Fig. 5), the average row of nodal points, (respectively, T _{(M / 2 + 0.5) 1} ÷ T _{(M / 2 + 0 , 5)} if M is an odd number and T _{1 (N / 2 + 0.5)} ÷ T _{M (N / 2 + 0.5)} if N is an odd number), for example, T ₁₃ and T ₂₃ in FIG. 5 (where also the nozzles P ₁₁ ÷ P ₁₅ ; P ₂₁ ÷ P ₂₅ with the corresponding axes C ₁₁ ÷ C ₁₅ and C ₂₁ ÷ C ₂₅ , intersecting the plane perpendicular to axis 2, respectively, are indicated at points T ₁₁ ÷ T ₁₅ and T ₂₁ ÷ Т ₂₅ ) is located along one axis (for example, 3 of FIG. 5) of second-order symmetry.

According to a third embodiment of the multi-jet former of the extinguishing powder stream, M and N are odd numbers. In other words, the nozzle contains a central pipe — P ₀₀ , an axis — C ₀₀ , which coincides with axis 2, and a bundle of an even number (for example, eight of FIG. 6) of peripheral pipes P ′ ₁₁ , P ′ ₁₂ , P ′ ₁₃ , (P _'13 not shown, P' _21, P _'23, P' _31, P _'32, P' _33, the axis C _'11 ÷ C' _13, C _'21, C' _23, C _'31 ÷ C' ₃₃ intersect the plane perpendicular to the axis 2 in the points: T _'11 ÷ T' _13, T _'21, T' ₂₃ and T * ₃₁ ÷ T _'33 axis peripheral nozzles are arranged at respective acute angles θ ₁₁ ÷ θ _13, θ _21. , θ _23, θ ₃₁ and θ ₃₃ (θ 6 corners ₁₃ and ₃₁ are not designated θ) to a plane perpendicular to the central axis 2. The axes and the periphery ynyh nozzles intersect the plane perpendicular to the axis 2 at the points respectively T _00, T _'11 ÷ T' _13, T _'21, T' _23, T _'31 ÷ T' ₃₃ that correspond to nodes of a flat rectangular lattice that is symmetric about underlying in the same plane two mutually perpendicular axes 3 and 4 of twofold symmetry along respectively the first row of grid points T _'12, T _00, T' _32, a flat rectangular lattice and orthogonally arranged to the first row of the second number of grid points T _'12, T _00, T _'32, flat rectangular (e.g., square) in D etki. Axles 3 and 4 a second-order symmetry intersect in a point situated on the axis 2. Similarly, as to the above-described second embodiment, the nozzle axis in each group of peripheral nozzles (namely: 1) R _'11, R' _12, R '₁₃; 2) R _'11, R' _21, R _'31; 3) P _'31, P' _32, P _'33 and 4) P' _13, P _'23, P' _33), the axes of which are located in a plane that intersects a plane perpendicular to the axis 2, on the line along some key points (namely, 1) T _'11, T' _12, T _'13; 2) T _'11, T' _21, T _'31; 3) T _'31, T' _32, T _'33 and 4) T' _13, T _'23, T' ₃₃₎ of the flat rectangular grid corresponding to a given group of peripheral nozzles are arranged at the same angle φ - relative to each other, but the exceeds half the angle - α aperture of the jet of gas powder mixture.

In the particular case of the invention, the axes of all the nozzles of the multi-jet former of the extinguishing powder flow intersect at one point (Fig. 3) located on the axis 2. In this case (according to the second and third embodiments of the multi-jet former of the extinguishing powder stream), the axis of the nozzles located in one planes and at the same angle φ relative to each other, essentially lie in the plane of the same face of the pyramid with four side faces.

In Fig. 7, the following notation is used: 11 — surface to be protected, 12 — zone of contact between the jets P ₁ and P _{2 of the} gas-powder mixture, corresponding to different multi-jet formers of the extinguishing powder stream; 13 - the projection of the zone 12 on the protected surface 11.

All nozzle nozzles (in all embodiments of the invention) are cylindrical in shape and have the same cross-sectional area. The nozzles may have a different shape, for example, preferably rectangular or square, as well as round, oval, elliptical or cross-sectional in the form of a regular polygon with more than four sides.

The angle α depends, in particular, on the ratio of the length of the nozzles to their caliber, for example, the cross-sectional area. It is advisable that the numbers M and N do not exceed 10.

The method of extinguishing a fire is as follows. Depending on the area of the surface to be protected, the required number of groups of jets of the gas-powder mixture directed to the fire source is formed. In this case, each group is formed in the form of a beam of jets of a gas-powder mixture directed at a fire source, in which the axes of adjacent jets are arranged at the same angle φ≤α / 2 relative to each other, the formation of each beam of jets of a gas-powder mixture directed at a fire source is carried out using multi-jet the former of the flow of extinguishing powder, the nozzle of which is made in the form of a bundle of nozzles, the axes of which are oriented in space in accordance with the selected (from the above) version of its implementation. Preliminarily, based on the specific geometrical parameters (area and shape in plan) of the surface to be protected, the required number of multi-jet formers of the extinguishing powder flow is set at a given height above it so that the peripheral zones of the adjacent multi-jet formers of the flow of extinguishing powder are mutually overlapped in the fire extinguishing zone. Since the shape of the surface area protected by each proposed multi-jet former of the extinguishing powder flow is close to rectangular, a uniform distribution of the specific consumption of extinguishing powder over the entire protected surface is ensured with a minimum amount of mutual overlap of the peripheral zones of the adjacent multi-jet former of the extinguishing powder flow. When a fire is detected, for example, the locking and starting device of the extinguishing powder supply system (not shown in the drawings) is triggered. As a result, the extinguishing powder (in the form of a gas-powder mixture) first enters the outlet pipe and then through the distribution pipelines into the inlet pipe 1 of the corresponding multi-jet former of the extinguishing powder stream. In the case of using devices for supplying extinguishing powder of a small capacity, the proposed multi-jet former of the flow of extinguishing powder is connected directly to its outlet head. At the outlet of the inlet pipe 1, the flow of the gas-powder mixture is separated by the pipes of the corresponding nozzle (Figs. 1, 4, 5 and 6). At the same time, there is a change in the direction of distribution of the separated volumes of the gas-powder mixture. As a result, jets of the gas-powder mixture emerging from each nozzle of the corresponding nozzle are formed and, it is also important, the mixture is additionally homogenized due to the destruction (possibly in it) of the extinguishing powder clots due to their multiple interaction with the inner walls of the nozzles of the corresponding nozzle.

Since the angle φ between the axes of adjacent nozzle nozzles does not exceed half of the aperture angle α of each jet P of the gas-powder mixture, at a certain distance from the nozzle, depending on the specific ratio between the angles φ and α, there will be mutual overlap of the peripheral sections of each pair adjacent jets P of gas-powder mixture (Fig. 1). To ensure the same specific consumption of extinguishing powder over the entire surface area protected by a single multi-jet former of the extinguishing powder flow, it is necessary that the specific consumption of extinguishing powder from each of two mutually overlapping peripheral jets of gas-powder mixture in the area of the fire source, corresponding to the intersection of the bisector of the angle φ between the axes of this pair of adjacent jets of a gas-powder mixture with a protected surface, amounted to approximately 50% of the specific consumption of extinguishing powder in the direction of the axis of each of these jets of the gas-powder mixture also in the focus of the fire. This condition is satisfied when the distance between the nozzle and the surface to be protected is appropriate for each multi-jet former of the flow of extinguishing powder.

To ensure the same specific consumption of extinguishing powder over the entire surface to be protected, multi-jet formers of the extinguishing powder flow are installed relative to each other at a distance that ensures, firstly, mutual overlap of the peripheral zones of adjacent surface areas protected by adjacent multi-jet formers of the flow of extinguishing powder. Secondly, it is necessary that in the center of the fire (on the surface to be protected) the specific flow rate of the extinguishing powder from each of the adjacent multi-jet formers of the flow of the extinguishing powder in the direction of the area of the surface to be protected 11, corresponding to the projection 13 on it of the contact zone 12 of their jets P ₁ and P _{2 of the} gas-powder mixture, amounted to approximately 50% of the specific consumption of extinguishing powder in the direction of the axis of each jet of gas-powder mixture also in the fire. It should be noted here that the specific consumption of the extinguishing powder in the direction of the axis of each jet of the gas-powder mixture in the fire zone is selected on the basis of the conditions for reliable fire extinguishing of a particular class.

The invention can be used to extinguish a fire in industrial facilities, in storage facilities, as well as in office buildings.

Claims (22)

1. A method of extinguishing a fire, including the formation of at least one group of jets of a gas-powder mixture directed at a fire source, characterized in that each group is formed in the form of a beam of jets of a gas-powder mixture directed at a fire source, with axes adjacent to each other in each beam the jets are placed at the same angle relative to each other, which does not exceed half the opening angle of the jets of the gas-powder mixture. 2. A multi-jet former of a stream of extinguishing powder containing an inlet pipe with a nozzle at its end, characterized in that the nozzle is made in the form of a bundle of pipes, the axes of which are located in the same plane with the axis of the inlet pipe and at the same angle relative to each other, which does not exceed half the angle of the jets of the gas-powder mixture. 3. The shaper according to claim 2, characterized in that the axes of all nozzle nozzles intersect at one point located on the axis of the inlet nozzle. 4. The shaper according to claim 2, characterized in that the nozzle nozzles are cylindrical in shape and have the same shape and cross-sectional area. 5. Shaper to claim 4, characterized in that the nozzle nozzles have a rectangular cross-sectional shape. 6. The shaper according to claim 4, characterized in that the nozzle nozzles have either round, or oval, or elliptical cross-sectional shape. 7. A multi-jet former for extinguishing powder flow, comprising an inlet nozzle with a nozzle coaxially located at its end, characterized in that the nozzle is made in the form of a bundle of an even number of nozzles, the axes of which are located at corresponding sharp angles to a plane perpendicular to the axis of the inlet nozzle, and intersect it at the points corresponding to the nodes of a planar rectangular lattice, which is symmetrical relative to two mutually perpendicular axes of symmetry of the second order lying in the same plane, parallel corresponding to the orthogonally located rows of nodal points of a flat rectangular lattice and intersecting at a point on the axis of the inlet nozzle, while the axis of the nozzles in each group of nozzles, the axes of which are located in the corresponding plane intersecting the plane perpendicular to the axis of the inlet nozzle, along a line along a series of nodal points of a flat rectangular lattice corresponding to this group of nozzles are located at the same angle relative to each other, which does not exceed half the opening angle jets of gas powder mixture. 8. The shaper according to claim 7, characterized in that the intersection point of the axes of symmetry of the second order coincides with the intersection point of the diagonals of the central cell of a flat rectangular lattice. 9. The shaper according to claim 7, characterized in that the middle row of nodal points of a flat rectangular lattice is located along one second-order symmetry axis. 10. Shaper according to claim 7, characterized in that the axis of all nozzle nozzles intersect at one point located on the axis of the inlet nozzle. 11. The former according to claim 7, characterized in that the nozzle nozzles are cylindrical in shape and have the same shape and cross-sectional area. 12. The shaper according to claim 11, characterized in that the nozzle nozzles have a rectangular cross-sectional shape. 13. The former according to claim 12, characterized in that the nozzle nozzles have a square cross-sectional shape. 14. The shaper according to claim 11, characterized in that the nozzle nozzles have either a round, or oval, or elliptical cross-sectional shape. 15. The shaper according to claim 11, characterized in that the nozzle nozzles have a cross-sectional shape in the form of a regular polygon with more than four sides. 16. A multi-jet former for extinguishing powder flow, comprising an inlet pipe with a nozzle coaxially located at its end, including a central nozzle and peripheral nozzles, characterized in that the central nozzle is made in the form of a central pipe located coaxially with the inlet pipe, and the peripheral nozzles in the form of a beam from an even number of peripheral pipes, the axes of which are located at corresponding sharp angles to a plane perpendicular to the axis of the inlet pipe, while the axes of the central and peripheral tubes cross the above plane at points corresponding to nodes of a planar rectangular lattice, which is symmetrical with respect to two mutually perpendicular symmetry axes of the second order lying in the same plane, located along the first and second orthogonally arranged rows of nodal points of the planar rectangular lattice and intersecting at a point on the axis the central pipe, while the axis of the pipes in each group of peripheral pipes, the axes of which are located in the corresponding plane, cross a plane that is perpendicular to the axis of the inlet pipe, along a line located along a number of nodal points of a flat rectangular lattice corresponding to this group of peripheral pipes, are located at the same angle relative to each other, which does not exceed half the opening angle of the jets of the gas-powder mixture. 17. The shaper according to clause 16, wherein the axes of all peripheral pipes intersect at one point located on the axis of the inlet pipe. 18. The former according to claim 16, characterized in that all nozzle nozzles are cylindrical in shape and have the same shape and cross-sectional area. 19. Shaper according to claim 18, characterized in that all nozzle nozzles have a rectangular cross-sectional shape. 20. The shaper according to claim 19, characterized in that all nozzle nozzles have a square cross-sectional shape. 21. Shaper according to claim 18, characterized in that all nozzle nozzles are either round, or oval, or elliptical in cross section. 22. Shaper according to claim 18, characterized in that all nozzle nozzles have a cross-sectional shape in the form of a regular polygon with more than four sides.

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