SU1680355A2 - Injector - Google Patents

Description

The invention relates to devices designed to obtain an aerosol, can be used in aircraft engine industry, The goal is to increase the dispersion of the aerosol by additional forced crushing. For this, the nozzle is equipped with a tank with a cryogenic substance 2

connected with her collectors. Each of the collectors is installed on the outer surface of the inner wall of the annular nozzle in front of the radial holes and is made with a slotted channel. The output section of each channel is located in a plane tangential to the side surfaces of the radial holes. A cryogenic substance, such as liquid nitrogen, acting on the liquid flowing out of the holes, instantly breaks up into droplets and in the gaps between them and the surface of the liquid, saturated vapor of the liquid is cooled to the boiling point of liquid nitrogen (-194 ° C). The result is a high degree of supersaturation, leading to abundant fog formation. 2 Il.

The invention relates to devices designed to obtain an aerosol, and can be used in aircraft engine manufacturing and chemical industry, and is an improvement to the nozzle described in auth.St. No. 1069865.

The purpose of the invention is to increase the dispersion of the aerosol by additional forced crushing,

Figure 1 shows the nozzle, a General view; figure 2 - section aa in figure 1.

The nozzle contains a pipeline 1 for supplying fluid, ending with a sleeve 2 with radial holes 3 and a bottom 4, and an air duct 5 covering the sleeve 2. The bottom 4 is pivotally connected to the adjustment screw 6.

In addition, the nozzle is provided with an annular nozzle 7 mounted coaxially with their sleeve 2 with radial holes 8 in the inner wall coinciding with radial holes 3 in sleeve 2 having an inlet 9 facing the air flow (shown by arrows) and an outlet 10, perpendicular air flow.

The nozzle is also equipped with a container 11 with a cryogenic substance, such as liquid nitrogen, and communicators 12 with a capacity of 11, each of which is mounted on the outer surface of the inner wall of the annular nozzle 7 before the radial hole 8 and fixed, for example, by welding.

1680355 A2

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Each collector is made with a slot channel 13, the output section of which

located in a plane tangential to the side surfaces of the radial holes

eight.

Each of the collectors 12, for example, is connected via pipelines 14 and 15 via an electromagnetic valve 16 to a container 11 containing a cryogenic substance.

The nozzle works as follows.

When the fluid is supplied through the pipeline 1, it is poured through the openings 3 in the sleeve 2 and the openings 8 of the inner wall of the annular nozzle 7 and flows in the air duct 5 in the form of streams. At the same time, the electromagnetic valve 16 opens, liquid nitrogen from the tank 11 flows through the pipelines 14, 15 to the collectors 12 and through the slotted channels 13 are fed out to the row of radial holes 8 in the inner wall of the annular socket 7. Liquid nitrogen, acting on the liquid, instantly breaks up into droplets and in the gaps between them and the surface of the liquids saturate nny fluid vapor is cooled to the boiling point of liquid nitrogen (-194 ° C);

The result is an extremely high degree of supersaturation, leading to abundant fog formation. The formed aerosol stream, which contains a significant part of the mist (1-3 μm), is affected by the air flow of the primary circuit and crushes those droplets that are not exposed to liquid nitrogen from the primary circuit. The aerosol flow is displayed in the incoming fresh air stream at an angle of 90 °, where ^z additional tionary is its fragmentation.

The mass flow rates of liquid and liquid nitrogen are determined, respectively, by the total area of the flow area of the holes 3 and 8, the slot channels 13 and the pressure drop across them. The ratio of mass flow rates of liquid and liquid nitrogen is determined experimentally from the condition of obtaining an aerosol spectrum with a high degree of dispersion.

The nozzle allows to obtain a smaller aerosol (with high dispersion), since in addition to the pneumatic spraying method, it uses a condensation spraying method using liquid nitrogen, as a result of which a part of the liquid turns into mist and the rest of the liquid is crushed in two steps of the nozzle by the incoming air flow .

The nozzle is applicable to obtain an aerosol from liquids that are not recommended to be heated, since aerosol fragmentation is forced by means of a cryogenic substance.

Claims (1)

Claim Nozzle auth. No. 1069865, characterized in that, in order to increase the dispersion of the aerosol by means of additional forced crushing, it is provided with a container with a cryogenic substance and manifolds communicated with it, each of which is mounted on the outer surface of the inner wall of the annular nipple in front of the radial holes and made with a slotted channel, the output section of which is located in a plane tangential to the side, the surfaces of the radial holes. 1680355 FIG. 2