RU2586556C1 - Liquid flow spreader of ejection type - Google Patents

Abstract

FIELD: technological processes; machine building.

SUBSTANCE: invention relates to spraying of fluids. In the liquid flow ejector-type spreader for atomizer to end surface of the captive nut axisymmetrically to a liquid flow spreader. Spreader consists of three coaxial pyramidal shells in the form of generating grids: outer, intermediate and inner. Each of the shells comprises a wire frame from two bases of square shape and lateral edges of a truncated pyramidal surface. Outer shell with smaller base is attached to the housing. Second, the larger base outer shell is simultaneously the bigger base of the intermediate shell with side ribs. Smaller base of the intermediate shell is simultaneously the bigger base of the inner shell with smaller base. Generating grids in the form of truncated pyramidal surfaces are arranged so that all their vertices lay on the axis coinciding with the casing axis. Direction of the vertices of the outer and the inner generating grids is the same. Top of the intermediate generating grid is directed opposite the outer and inner generating grids in the side of throttle washer with jet.

EFFECT: high efficiency of spraying.

1 cl, 2 dwg

Description

The invention relates to techniques for spraying a liquid.

The closest technical solution to the claimed object is a liquid flow divider according to patent RU No. 2450837, A62C 31/02 (prototype), comprising a hollow cylindrical body with a throttle washer connected to a union nut to which the liquid flow divider is mounted, made in the form of two in series connected meshes, one of which has the shape of a circle, and the other - hemispheres.

The technical result is an increase in the efficiency of fine atomization of a liquid.

This is achieved by the fact that in the ejection-type liquid flow divider for the nozzle, which contains a hollow body, consisting of a cylindrical part with an external thread for connecting to the nozzle of the distribution pipe for fluid supply, and a union nut fixed to the lower part of the body with the liquid flow divider, and a cylindrical hole is made coaxially to it in the housing, in the upper part of which a strainer is installed, and in the lower part - a throttle washer with a nozzle, to the end surface of the axle nut The flow splitter is mounted metrically to the body, which consists of three coaxial, coaxially arranged pyramidal shells in the form of generating grids: external, intermediate and internal, each shell containing a wire frame of two bases in the form of a square and side edges of a truncated pyramidal surface, the outer shell is attached to the body with a smaller base, and its second, larger base is at the same time a large base of the intermediate shell with side ribs, and its smaller base At the same time, the base is the large base of the inner shell with a smaller base, and the generating grids in the form of truncated pyramidal surfaces are located in such a way that all their vertices lie on the axis coinciding with the axis of the housing, the direction of the vertices of the external and internal generating grids coincides, and the vertex of the intermediate generating the grid is directed opposite to the vertices of the external and internal generating grids, and toward the throttle washer with a jet.

In FIG. 1 is a diagram of an ejector-type liquid flow divider assembly with an nozzle; FIG. 2 - general view of the divider.

Ejection-type liquid flow divider for the nozzle, which contains a hollow body 1, consisting of a cylindrical part with an external thread for connection to the nozzle (not shown) of the distribution pipe for fluid supply, and a union nut 6 attached to the lower part of the body with the flow divider 7 liquids. In the housing 1, a cylindrical hole 2 is made coaxially with it, in the upper part of which a strainer 4 is installed, and in the lower part there is a throttle washer 3 with a nozzle 5.

A divider 7 is mounted axisymmetrically to the housing 1 to the end surface of the union nut 6, which consists of three coaxial pyramidal shells 8, 9, 10 coaxially arranged in the form of generating grids: external 8, intermediate 9 and internal 10. Each of the shells contains a wire frame of two bases in the form of a square and side edges of a truncated pyramidal surface. The outer shell 8 with a smaller base is attached to the union nut 6, and its second, larger base is simultaneously the larger base of the intermediate 9 shell with side ribs, and its smaller base is simultaneously the larger base of the inner 10 of the shell with a smaller base. Generating grids in the form of truncated pyramidal surfaces are arranged in such a way that all their vertices lie on an axis coinciding with the axis of the housing 1, and the direction of the vertices of the outer 8 and inner 10 of the generating grids coincides, and the vertex of the intermediate 9 generating grid is opposite to the vertices of the outer 8 and inner 10 generating grids, and towards the throttle washer 3 with nozzle 5.

Perforation on the outer shell 8, from the side of the fastening of its truncated pyramidal surface to the end surface of the union nut 6, is made with a smaller pitch and a large diameter of the holes, contributing to the enhancement of the ejection effect.

Perforation of the inner shell 10 on the base, facing away from the throttle plate 3 with the nozzle 5 and made in the form of a square, has a larger diameter of the holes, contributing to the enhancement of the ejection effect and the range of the sprayed stream.

The ejection-type liquid flow divider for the nozzle operates as follows.

At the beginning of the formation of the torch, the sprayed liquid stream has the highest speed and when it hits the generating grid, foam is formed with small air bubbles (2–3 mm across) due to air ejection through the grids 8, 9, 10 of the divider 7, and with the distance from the nozzle 5, the jet velocity decreases and then foam with larger bubbles (4 ÷ 12 mm across) of air forms on the mesh. Thus, the divider produces polydisperse (differently sized for bubbles) foam, which has the property of rapid spreading over the surface. Obtaining foam is carried out according to the principle of ejection of air by sprayed jets of liquid in the divider 7.

The proposed nozzle divider design can be used as a fine spray gun in fire fighting equipment, for example, as a part of sprinkler or deluge fire extinguishing systems, in agriculture - for spraying various types of substances on sown areas and in industrial premises, as well as in chemical technology devices and in the power system - for fuel spraying, as well as in industries where the generation of atomized fine-dispersed fluid flows is required both in closed and open spaces Attribution.

Claims (1)

Ejection-type liquid flow divider for nozzle, which contains a hollow body, consisting of a cylindrical part with an external thread for connection to the nozzle of the distribution pipe for fluid supply, and a union nut with a liquid flow divider fixed to the lower part of the body, and cylindrical a hole, in the upper part of which a strainer is installed, and in the lower part - a throttle washer with a nozzle, characterized in that the axis nut is axially symmetrical to the end surface of the union nut A fluid flow divider is attached to the housing, which consists of three coaxial, coaxially arranged pyramidal shells in the form of generating grids: external, intermediate and internal, each shell containing a wire frame of two bases in the form of a square and side edges of a truncated pyramidal surface, the outer shell is attached to the body with a smaller base, and its second, larger base is at the same time a large base of the intermediate shell with side ribs, and its smaller base e is simultaneously a large base of the inner shell with a smaller base, and the generating grids in the form of truncated pyramidal surfaces are arranged in such a way that all their vertices lie on an axis coinciding with the axis of the housing, and the direction of the vertices of the external and internal generating grids coincides, and the vertex of the intermediate generating the mesh is directed opposite to the vertices of the external and internal generating grids, and towards the throttle washer with a jet, and the perforation on the outer shell from the side of the cr of fusion of its truncated pyramidal surface to the end surface of the union nut is made with a smaller pitch and a large diameter of the holes, which enhance the ejection effect, the perforation of the inner shell on the base facing away from the throttle washer with the nozzle and made in the form of a square has a larger diameter of the holes, contributing to the enhancement of the ejection effect and the range of the sprayed stream.

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