SU835509A1 - Sparyer - Google Patents

Description

According to the invention, the nozzle mounted on what has a porous shell and a cavity for supplying compressed gas in communication with its source, and a source of supplying the sprayed substance to the porous shell in accordance with the invention. in the form of a concave paraboloid of rotation, with the cavity for feeding the compressed gas formed by the porous shell and the wall of the disk. In addition, the sprayer can be equipped with a rotating disk with an impeller in its cavity, mounted above the nozzle coaxially with the latter and communicating with the source of the sprayed substance, can be equipped with a new disk installed under the force nozzle: coaxially with the latter and communicating with the source of the sprayed substance, or two rotary discs communicating with the source of the substance to be distributed, one of which is equipped with an impeller placed in its cavity and mounted above the nozzle coaxially to the latter, and the other under the nozzle with posledgney clear.

FIG. I shows a diagram of a spray with one main disk; in fig. 2 is a diagram of a spray with one disc and a peripheral part, porous or quick-detachable, solid; in fig. 3 is a diagram of the dispatcher with an additional disk located above the main one; in fig. 4 is a diagram of an atomizer with an additional disk, located on the main node; in fig. 5 is a diagram of the operation of the sprayer shown in FIG. one; in fig. b - spray pattern through the porous shell; ia fit. 7, 8 and 9 is a diagram of the operation of the sprayer shown in FIG. 3, 2 and 4 respectively.

The atomizer contains an irrigation shaft /, installed in the heel; n, nix 2; connected to Drive 3 Transmission 4, Mount-irovapny on the shaft of the force; m; at 5 in the form of a cone-shaped disk 6, Immayuschy porous sheath 7, and cavity 8 for supplying compressed gas connected to a source of compressed gas (not shown in drawing not shown) through channel 9 ivala and the source feed the sprayed substance (in the drawings, no, not indications) to the porous shell through the channel 10 of the shaft.

The porous shell 7 is placed in the disk 6 "is made in the form of a concave paraboloid of rotation, wherein the cavity 8 for supplying the fused gas is formed by the shell 7 and the wall of the disk 6.

Parameters of the paraboloid are calculated depending on the specific gravity of the sprayed substance and the speed of rotation of the disk 6.

In a nebulizer, the paraboloid can have only the central part P of the casing 7, and its peripheral part 12 can have a Forma Flat O ring (Fig. 2, I) of a SLI cone 13 (Fig. 2, II), coupled to the paraboloid. The cone 13 is made quick detachable with different angles a. As a source of compressed gas (air), it may be necessary to use the impeller of the fan -.14.

The atomizer can also be equipped with a rotary disk -75 with an impeller 16 in its cavity (fit. 3) installed above the nozzle 5 coaxially and last communicating with the source of the sprayed substance through the tube 17 and channel 10, or the rotary disk 1-8. - connected under the nozzle 5, it communicates with the source of the sprayed substance (Fig. 4) OR by two rotary disks 15 and 18, which communicate with the source of the sprayed substance, one of which 15 is impeller 16 placed in its cavity and is installed | Vlen over the nozzle 5 coaxially last and the other 18 - under the nozzle J coaxial to her.

An atomizer assembled according to FIG. 1, works as follows

(f. IG. 5 1 6).

Along the arrow A, along channel 10, the atomized substance is continuously fed into the disk 6, along the arrow B - compressed gas (air). The spraying disk 6 in the direction of arrow G also gives the flowing sprayed substance in the form of a paraboloid of rotation around the F – O axis and a porous envelope 7 forms a layer D of constant thickness over its entire surface. The passage through the pores 19 of the sheath 7 along arrow E, millions of gas streams, expand in layer D under sudden pressure, destroy the layer and carry away a fine-dispersed torch along arrow G.

Due to the rotation and centrifugal forces and due to the movement of the expanded air masses in arrow E, the flake deflects to the periphery in arrows Zh, Zh2, Zhz, and then falls by a wide annular flow with width Zh4. Excess part of the substance breaks off from disk 5 and with great speed by powerful structures. mi And at an angle p, radially, then crushed from contact with the atmosphere and falls in the form of a powerful circular torch

The sprayer shown in FIG. 7 and 8, works similarly. In addition to the same G and I streams, in this case, an additional stream K, which is thrown out by the disk 15, is added to the streams I and F and increases the long-term effect without deteriorating the uniformity of spraying, and the gas stream B increases the long-range flow of the stream J.

Spray on fit. 8 because of the presence of 1 cone M on the main disk and a sharp increase in angle a, provides intersection and interaction also of the flows I and K,

which contributes to additional fragmentation of the substance and increase the dispersion of the torch.

In the sprayer “and FIG. 9, the flux Ж interacts twice with the fluxes Я and Л and the size of the ring expands significantly from Ж4 to Жз.

The given patterns of operation of the sprayer provide an idea of only a small part of the possible combinations of the torch, which make it possible to increase the efficiency of the spraying process — to expand the scope of the sprayer. Known dispensers do not have such a variety of means to influence the torch. The proposed sprayer has jet streams of sprayed matter, a thin spray of pneumatic spray. The interaction of both types of torch and their mutual interaction allow expanding or narrowing one or another spray area, increasing or decreasing the long-range response, increasing or decreasing the dispersion of the torch in a given zone. At the same time, the nebulizer is simple in design, characterized by wide changeover capabilities.

 the invention

Claims (4)

1. The atomizer, which contains: the drive shaft, the nozzle mounted on it, has a porous casing and a cavity for supplying compressed gas, 1 coax, ayush; the uyus with its source, and the source of supplying the sprayed attachment to the porous casing; about tl, and h and s, and with the fact that, in order to increase the efficiency of the spraying process and expand the technological capabilities of the atomizer, the nozzle is made in the form of a cone-shaped disk, and the porous shell is stirred in it and made in the form of a concave paraboloid margins, while the cavity for feeding is compressed of gas formed porous shell and the disc wall. 2. The sprayer according to claim. 1, characterized in that it is provided with a rotary disk with an impeller in its: cavity, installed above the nozzle coaxially with the latter and communicating with the source of sprayed suspension. 3. The Rasnylitel according to claim 1, of which is provided with a rotary disk installed under the nozzle coaxially last and communicated with the source of the sprayed substance. 4. The sprayer according to claim 1, which is also distinguished by the fact that it is equipped with two rotary disks communicating with the source of the sprayed substance, one of which is equipped with an impeller placed in its cavity, and the pad is installed with a nozzle coaxially last, and the other is under the nozzle coaxially last. Sources of information taken into account in the examination: 1. Author's certificate CGCP № 138705, cl. A 61 K 35/16, 1960. 2. USSR author's certificate for application No. 2536186 / 23-05, cl. B 05 B 7/24 ,. 1977 (prototype). W; T   11 - :, I At 7111 V I v .. f  i fGi. nil U: Lb - //. W / G: °:: W; o o (L ° "SSS" 5 schg casTsa j. In li a o o o u u s, o ° o o o o S 00 00 .00 s; s-vvl. Y, -S-- -S C “- o o g:. Ltd . O o o o o o o o o o o o ° ° o % csv O O aa oi ° O o-1 U f, o% 00 o aa o., O. о о ° о о о о 0 ° 0 ° ° о .7, GA; : F; / ;; 3 about   ° ° ° 00 oo o Q o o s, ioooooo o o os