RU163093U1 - SPRINKLER SPRAY - Google Patents

Abstract

A sprinkler nozzle comprising a hollow cylindrical body with an internal working chamber, with a translationally located valve in it, a heat lock connected to the valve, nozzles located in the body wall and connected in the internal working chamber, characterized in that the cylindrical body is additionally made stepwise, while the upper stage of the housing has a number of nozzles, which contains an even number N of holes, made with the possibility of forming a symmetric external a high-capacity extinguishing agent spray jet, the lower stage of the casing is made smaller in diameter than the upper stage, has a series of nozzles, which contains the number n = N / 2 of openings, is configured to form an internal spray torch concentric with an external flame with an output half as high productivity of the upper row, in addition, the nozzles of the upper row are displaced relative to each other in a circle at an angle γ, each nozzle of the lower row is offset from a pair of nozzles of the upper p and an angle γ / 2, the angle of inclination to the atomizer axis at the top row of nozzles greater than the angle of inclination of the lower row of nozzles.

Description

The utility model relates to the field of fire fighting equipment and is designed to extinguish fires with sprinkler systems with finely sprayed water.

The closest in technical essence and characteristics is a sprinkler-type fire extinguishing device containing a symmetrical cylindrical body with an internal working chamber connected to a water supply channel having a thermal lock made in the form of a glass heat-sensitive bulb connected to a valve installed with the possibility of translational movement in internal working chamber, jet nozzles installed at an angle in the lateral directions in a circle at a certain distance from each other uga (see. US Patent 20140367125 A1).

A disadvantage of the known device is the uneven distribution of atomized water over the protected volume.

The technical problem to which the utility model is directed is to obtain a more uniform distribution of the fine-dispersed droplet droplet flow over the volume of the protected object.

The problem is solved in that the sprinkler nozzle containing a hollow cylindrical body with an internal working chamber, with a valve located therein with the possibility of translational movement, a heat lock connected to the valve, nozzles located in the wall of the body and connected in the inner working chamber, according to the useful models, the cylindrical body is additionally stepped, while the upper stage of the body has a number of nozzles, which contains an even number N of holes, made with possible the formation of a symmetric external flame spray extinguishing agent with high performance, the lower stage of the housing is made smaller in diameter than the upper stage, has a number of nozzles, which contains the number n = N / 2 holes, is configured to form a concentric internal flame spray with an external flame with a performance two times lower than the productivity of the upper row, in addition, the nozzles of the upper row are displaced relative to each other in a circle at an angle γ, each nozzle of the lower row is sm relative to the pair of nozzles of the upper row at an angle γ / 2, and the angle of inclination to the axis of the sprayer at the nozzles of the upper row is greater than the angle of inclination of the nozzles of the lower row, ensuring concentricity of the rows.

The technical result provided by the given set of features is the increased uniformity of the sprayed extinguishing agent in the volume of the protected object due to the presence of two concentrically arranged rows of nozzles, providing the formation of two different concentrically arranged spray nozzles, namely: an internal one with a small opening angle of the torch and an external one with an increased opening angle flare with increased productivity compared to the performance of the internal flare.

A more detailed description of the sprinkler atomizer is based on the drawings in FIG. 1, FIG. 2, FIG. 3.

FIG. 1 - a General view of the sprinkler atomizer (in section) in running order.

FIG. 2 is a bottom view of a sprinkler atomizer.

FIG. 3 - General view of the sprinkler spray (in the context) when triggered.

The sprinkler spray consists of a cylindrical stepped case 1, a row of nozzles 2 is made in the upper step, a row of nozzles 3 in the lower step, nozzles are connected to the inner working chamber 4. Each nozzle is made in the form of a hole of variable diameter, smaller cross section 5 and larger cross section 6 are made identical in all nozzles.

The top row of nozzles 2 has an even number of holes N from row 6, 8, 10, 12, which are made symmetrically at an angle α to the axis of the spray gun and an angle γ relative to each other, and the bottom row of nozzles 3 has the number of holes n = N / 2 made symmetrically at an angle β to the axis of the sprayer, and in addition, each hole in the lower row is offset from the pair of nozzles in the upper row by an angle γ / 2.

In the lower part of the atomizer body, a lattice element is made up of four arcuate racks 7 conjugated at the lower point and made at the same time. The interface of the racks is designed to install the lower supporting surface of the glass thermosensitive flask 8. Each of the racks has an offset relative to the axial plane of the sprinkler, and, accordingly, a displacement of pairs of opposite racks relative to each other is formed, which together provides the maximum contact surface area with the end of the heat-sensitive bulb.

The lattice element of the atomizer communicates with the working chamber through the hole 9 in the housing.

In the working chamber of the sprayer there is a movable rod 10 with a polyurethane sealing collar 11 installed on it, the outer diameter of which corresponds to the diameter of the working chamber of the sprayer 4, and the inner diameter corresponds to the diameter of the landing on the stem.

The rod, with its lower end, rests on the upper supporting surface of the thermosensitive flask, while the sealed nose of the thermosensitive flask is located in a special recess 12 of the rod. In this position of the rod, the upper edge of the cuff is above the level of connection of the nozzles 2 and 3 with the spray chamber.

At the entrance to the working chamber of the spray filter is installed stainless steel mesh 13, which is fixed by the snap ring 14.

для монтажа в муфту 15, закрепленную на распределительном трубопроводе системы пожаротушения. Для создания необходимого момента затяжки резьбового соединения служат две лыски под ключ 16, выполненные на нижней ступени корпуса 1.The spray has an external thread

for installation in a sleeve 15 mounted on the distribution pipe of the fire extinguishing system. To create the required tightening torque for the threaded connection, two turnkey flats 16 are used, made on the lower stage of the housing 1.

To ensure the tightness of the connection between the sprayer and the coupling, a polyurethane sealing ring 17 is installed on the sprayer body, which fits snugly to the body along a specially made groove having a radius corresponding to the radius of the cross-section of the sealing ring.

In the standby mode of operation of the fire extinguishing installation in the distribution pipeline, on which the atomizers are installed, a pressure of 1-1.5 MPa is maintained. Water pressure acts on the stem 10 and the sealing sleeve 11 installed on it, while the stem 10 is supported by a heat-sensitive flask 8, and the sleeve 11 by working surfaces tightly contacting the wall of the working chamber 4 and the stem diameter of the rod 10, ensures the tightness of all the nozzle openings.

When a fire occurs in the room in which the atomizer is installed, a special liquid in the glass thermosensitive flask 8 expands with increasing temperature, which leads to its destruction (see Fig. 3). Water under pressure pushes the rod 10 with the sleeve 11 down the working chamber 4 until it stops, while the lower part of the rod 10 leaves the working chamber 4 through an opening in the housing 9. In this position of the rod 10, the nozzle passages 2 and 3 are released for the pumps to pass under high (10-15 MPa) water pressure, and the cuff 11 ensures the tightness of the holes 9 in the housing.

To protect nozzles 2 and 3 from clogging, the filter screen 13 has a mesh size of 80% of the cross-sectional diameter 5.

As a result, the sprinkler sprinkler at the outlet forms two symmetric spray nozzles concentrically arranged in one another, while the internal spray jet is smaller in volume and is formed by the n-number of nozzles, the external spray jet is larger in volume and formed by the 2n-number of nozzles. Thanks to this distribution of the total flow, higher spray uniformity is achieved.

The foregoing detailed description with reference to FIG. 1, 2, 3 indicates a sufficiently high-quality study of the design features of the proposed technical solution, convinces of the possibility of industrial application.

Claims (1)

A sprinkler nozzle comprising a hollow cylindrical body with an internal working chamber, with a translationally located valve in it, a heat lock connected to the valve, nozzles located in the body wall and connected in the internal working chamber, characterized in that the cylindrical body is additionally made stepwise, while the upper stage of the housing has a number of nozzles, which contains an even number N of holes, made with the possibility of forming a symmetric external a high-capacity extinguishing agent spray jet, the lower stage of the casing is made smaller in diameter than the upper stage, has a series of nozzles, which contains the number n = N / 2 of openings, is configured to form an internal spray torch concentric with an external flame with an output half as high productivity of the upper row, in addition, the nozzles of the upper row are displaced relative to each other in a circle at an angle γ, each nozzle of the lower row is offset from a pair of nozzles of the upper p and an angle γ / 2, the angle of inclination to the atomizer axis at the top row of nozzles greater than the angle of inclination of the lower row of nozzles.

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