RU1835316C - Device for the atomizing liquids - Google Patents

Abstract

Usage: irrigation of household plots. SUMMARY OF THE INVENTION: A device for spraying liquids is provided with an insert with an outlet installed in the outlet of the atomizer. The area of the hole is chosen to be a smaller cross-sectional area of the sleeve channel. The axis of the grooves on the opposite ends of the atomizer are directed in opposite directions relative to each other. The angle of inclination of the plane of the grooves to the radius of the outlet of the nozzle is chosen smaller than the angle of inclination to its longitudinal axis. The liner is installed with the separation of the cavity of the atomizer and the grooves into parts, in each of which the axis of the grooves are directed in opposite directions. 5 ill.

Description

The invention relates to devices for spraying liquids and can be used to irrigate household plots,

The purpose of the invention is to increase uniform irrigation density and dispersion.

Figure 1 shows a device for spraying liquids, a general view; figure 2 - cross section aa in fig. 1; in Fig.3 - the location of the grooves at an angle of 30 ° to the axis of the nozzle opening and at an angle of 20 ° to the radius of the outlet of the latter; figure 4 is a section bB in Fig.Z; figure 5 - section bb in fig.Z.

A device for spraying liquid. comprises an atomizer 2 fixed in the housing 1 with side grooves 3 and an outlet 4, axially displaced by an adjusting sleeve 5 with a channel 6 and forming a cavity 7 with the atomizer 2.

The grooves 3 are located in a plane inclined to the longitudinal axis of the nozzle at an angle / and to the radius of the outlet 4 at an angle D, while 2 (a + / 3) of the plane inclination is selected no more than 80 °.

A liner 8 is installed in the outlet 4 of the nozzle 2, which divides the nozzle 2 in no two parts, while the area of the outlet of the liner 8 is less than the cross-sectional area of the channel 6 of the adjusting sleeve 5. A channel 9 connected to the pipeline serves to supply fluid (not shown ) and holes 10 (see Fig. 1,2).

A device for spraying liquid operates as follows.

The liquid from the pipeline through the channel 9 and the hole 10 enters the cavity 7, from there through the grooves 3. located in the plane inclined to the radius of the hole 4 of the spray gun 2 and its longitudinal axis, in the cavity 11 and 12 of the Central hole 4

00 CA

SL

with

duster 2 (Fig. 1), where the jets and liquids swirl and form multidirectional flows (Figs. 3,4,5), which exit through the bore 6 of sleeve 5, fly apart with a finely dispersed uniform wide fan. The size of the liquid spray jet is controlled by axially moving the sleeve 5 relative to the housing 1. When removing the sleeve 5 relative to the housing 1, a gap is formed between the ends of the sleeve 5 and the atomizer 2, while part of the fluid flow enters from the cavity 7 through the gap between the ends of the sleeve 5, then the amount of fluid flowing through the grooves 3 and the opening 4 of the atomizer 2 is reduced and the rotational effect of the fluid flow is formed, a powerful fluid jet is formed. In the absence of a gap between the ends of the sleeve 3 and the nozzle 2, a liquid flow is generated with a significant multidirectional rotational effect, and when leaving the hole b of the sleeve 4, the liquid flow scatters into a finely dispersed uniform spray of liquid, covering a significant area of the irrigated surface of the sections.

In Fig.3 shows a spray 2 (top view); figure 4 - the location of the grooves in the cavity 11, figure 5 - the location of the grooves in the cavity 12, while the liner 8 is installed so that it divides the grooves 3 into two parts, and is a common wall for the cavities 11 and 12 , thereby dividing the fluid flows, in which the rotation is directed in opposite directions relative to each other. From the cavity 11, the swirling tray enters through the opening of the insert 8 into the channel 6, from the cavity 12, the oppositely swirling flow also enters the channel 6 of the sleeve 5, in the channel 6 the flows are interconnected and the latter interact. Due to friction between the fluid layers, intermolecular bonds are destroyed, and pulsations (oscillations) arising due to friction between the molecules lead to additional crushing, as if a fluid particle burst when leaving channel 6, a circulation is created, resulting in a finely dispersed spray of liquid. At

In this case, the rotational flow exiting the cavity 12 will expand to a larger radius, the boundary of the rotational flows in the channel 6 will have a straight direction and will be further crushed.

a rotating stream exiting the cavity 11, thereby creating a uniform irrigation density over a larger area, while the area of the outlet of the concentric sleeve should be less

the area of the outlet 6 of the sleeve 5. The invention can also be used when washing motor vehicles and mixing liquids.

Formulas of the invention

A device for spraying liquids, comprising a housing, an axially movable sleeve with a channel and a nozzle mounted in the housing with an outlet and side

grooves located in a plane inclined to the radius of the outlet of the spray gun and its longitudinal axis with the sum of the angles of inclination of the plane selected no more than 80 °, characterized in that,

in order to increase the uniform density of irrigation and dispersion of the spray, it is equipped with a liner installed in the outlet of the spray nozzle with an outlet, the area of which

a smaller part of the cross section of the bushing channel was selected, while the groove axes at opposite ends of the spray gun are directed in opposite directions relative to one another, the angle of inclination of the plane of the grooves to the radius of the outlet of the spray gun is chosen smaller than the angle of inclination to its longitudinal axis, and the insert is installed with separation of the cavity sprayer and grooves into pieces in each of

whose axis of the grooves are directed in opposite directions.

1 gpf

 % of%

91S2Sh

5-6

2 °°

FIG. 5