RU2101615C1 - Injector - Google Patents

Abstract

FIELD: power engineering; spraying liquids in sprinkling systems and fuel burning systems. SUBSTANCE: injector has body 1 with nozzle consisting of contraction section 2 and diffuser section 3 with resonator 4 located between them. Injector is also provided with side outlet holes 5 in diffuser section 3 and elements for guide discharge of flow towards outlet section 9 of diffuser section 3 connected to this section of nozzle. Discharge guide elements are made in form of baffles 7 embracing diffuser section 3. Thus highly turbulized turbulent flow is formed due to non-coaxial opposite interaction of main flow with secondary flow. EFFECT: increased degree of spraying. 3 dwg

Description

 The invention relates to devices for spraying liquids, and can be used to work in sprinkler installations, fuel-burning devices.

Known nozzle containing a housing, a nozzle with confuser and diffuser sections and a resonator located between them [1]
The disadvantage of this nozzle is the insufficient degree of spraying when changing the conditions determining the spray (flow parameters, type of sprayed liquid, etc.), which, in turn, reduces the efficiency of the device. In this device, the atomization of the liquid is due to its oscillation during the passage of the annular cavity cavity.

 Also known is an injector [2] comprising a housing with a nozzle consisting of confuser and diffuser sections, between which there is a resonator made in the form of an annular cavity, lateral outlet openings made in the diffuser section, and flow discharge direction elements towards the outlet section of the diffuser section connected to the diffuser portion of the nozzle.

 However, the degree of spraying of the flow is insufficient and is due to its oscillation during the passage of the annular cavity and in the interaction of the outgoing coaxial satellite flows.

 The objective of the invention is to increase the degree of spraying.

 This problem is achieved in that the elements of the flow discharge direction are made in the form of a visor covering the diffuser section with the formation of an annular visor slit consisting of arcuate trapezoidal rotary plates pivotally attached to the diffuser section in front of its outlet openings along the flow, with the plates mounted one relative to the other overlapping and the visor is equipped with a flow reflector, made in the form of flanges attached to the plates, bent towards each other, and placed on flanges of unidirectional ribs.

 In FIG. 1 shows a nozzle, a General view in section; in FIG. 2 is a view along the arrow in FIG. one; in FIG. 3 section BB in FIG. one.

 The nozzle comprises a housing 1 with a nozzle consisting of a confuser 2 and a diffuser 3 sections, between which there is a resonator 4 made in the form of an annular cavity, lateral outlet openings 5 made in the diffuser section 3, and elements of the direction of discharge flow towards the outlet section 9 of the diffuser section 3, connected to the diffuser section 3 of the nozzle. The elements of the direction of discharge of the flow are made in the form of covering the diffuser section 3 with the formation of the annular outlet slit 13 of the visor 7, consisting of arcuate trapezoidal rotary plates 10, pivotally 6 attached to the diffuser section 3 in front of its lateral outlet openings 5 along the stream, and the plate 10 is installed one relative to the other lap, and the visor 7 is equipped with a flow reflector 8, made in the form of flanges 8 attached to the plates 10, bent towards each other, and placed on the flanges 8 x 11 unidirectional edges.

 The nozzle works as follows.

 The sprayed medium from the confuser section 2 of the nozzle enters the annular cavity of the resonator 4, where the constant pressure is converted to variable, and exits through the diffuser section 3 of the nozzle into the outlet section 9 (main stream) and the lateral outlet openings 4 (secondary stream), from where it flows separately streams. The secondary stream moves further along the rotary plates 10 and after a turn continues to move along the flanges 8 towards the main stream flowing from the outlet section 9 of the diffuser section 3 of the nozzle. As a result of the collision of the secondary stream with the main, the medium is sprayed. When turning the rotary plates 10, the degree of dispersion of the outflowing medium is controlled by changing the collision angles of the secondary stream with the main stream, by changing the initial parameters of the colliding jets.

 At certain turning angles of the flanging plates 10, the flanges 8 no longer overlap, but form gaps 12 through which part of the secondary stream flows into the surrounding space in the form of separate streams, which are sprayed faster when interacting with the surrounding air. By installing flanges 8 ribs 11 having the same direction of inclination, the twisting of the secondary stream is achieved. The swirling secondary stream substantially turbulizes during the interaction the main stream due to the presence of the tangential velocity component, penetrates deeper into the main stream, which contributes to an increase in the degree of atomization of the outflowing jet.

 The retention of the plates 10 in a certain angular working position is achieved by securing them using the lining 14.

 Thus, the effectiveness of the use of the present invention is to create a spray stream due to the misaligned counter-interaction of the main stream with the secondary and the formation of a highly turbulent total stream.

Claims (1)

 An injector comprising a housing with a nozzle consisting of a confuser and diffuser portions, between which a resonator made in the form of an annular cavity is located, side outlet openings made in the diffuser portion, and flow discharge direction elements towards the outlet cross section of the diffuser portion connected to the diffuser portion nozzle, characterized in that the elements of the direction of discharge are made in the form of covering the diffuser section with the formation of an annular outlet slit of the visor, consisting of an arc trapezoidal rotary plates pivotally attached to the diffuser section in front of its lateral outlet openings, the plates being installed one relative to the other overlap, and the visor is equipped with a flow reflector made in the form of flanges attached to the plates, bent towards each other, and placed on flanging unidirectional ribs.

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