HU212743B - Fluid pulverizer operating by gas pressure preferably one of compressed air - Google Patents

Abstract

The present invention relates to a gas pressure, preferably a compressed air fluid injector, a housing, an air and a liquid delivery tube, the housing (1) preferably having a threaded pneumatic cylinder (2), a housing (1) and a lower, smaller outer diameter of the pneumatic cylinder (2). (3), an air supply pipe (4) connected to the upper part (1) of the pneumatic cylinder (2), an inlet pipe (14) connected to the housing (1) and discharging into the liquid space (3), an air space (5) in the interior of the pneumatic cylinder (2), a piston (6) arranged at the end in the air space (5) formed as the end piston needle valve (11), above the air inlet pipe (4) on the valve stem (6) , between the valve stem (6) and the pneumatic cylinder (2), a ring (19) placed under the air inlet tube (4) in the valve stem (6) in the area of the ring (19) has an inclined bore (18). At the lower part of the pneumatic cylinder (2), a tapered air nozzle (10) is formed, the spacer spacer (17) arranged around the tapered air nozzle (10), the valve stem (6) disposed between the valve stem (6) and the pneumatic cylinder (2). guide nozzle (9), nozzle (12) with bottom thread, preferably threaded, threaded to the housing (1), threaded cap (15), threaded to upper part of pneumatic cylinder (2), in pneumatic cylinder (2) ) the spring (16) arranged between the piston (7) and the closure cap (15) is preferably arranged around the valve stem (6) by means of a pressure plate (20). 9 IT io_ Irish 15_ 16 Σ 4 3 2P 7 n I ob'e n 6 13 EN 212 743 B Scope of the description: 4 pages (including 1 page figure)

Description

Scope of the description: 4 pages (including 1 page figure)

EN 212 743 Β

The present invention relates to a liquid sprayer operating with gas pressure, preferably compressed air, whose moving piston system controls the amount of fluid sprayed.

Many versions of the pneumatic fluid sprayer are known from the literature and practice. József Túrba. Atomizers (Technical Publisher Budapest, 1976) II. The classification of the nebulizers from the section entitled "4th pneumatic nebulizers" shows that the atomization mechanism is a two-step operation, where one of the steps is the so-called. fiber or ribbon formation due to air friction, then the second step to drop these strips into droplets according to Rayleigh's theory. There are two variants of droplet degradation. In one embodiment, the drop will gradually encounter an increasing velocity of air. The other happens when the drop is subjected to a sudden change in air speed.

In the case of internally blended pneumatic nebulizers, the fluid enters the cylindrical mixing area (Fig. 11-181) with an overpressure at the centrally located circular opening, where the compressed air flowing out of the circular cross section is mixed. The decomposition of the liquid by compressed air begins in the mixing area and ends immediately after the mouth opening. The kinetic energy of the two currents is fine droplet size. results in telescopic spraying.

The external blend pneumatic nebulizers are equipped with a liquid deflector, a cleaning needle and a control needle. The air or gas can be set with an air cap. As the air volume decreases, the atomizer beam angle decreases.

A bi-directional nebulizer is shown in Figure II-197. FIG. This atomizer combines the principle of internal and external mixing. The centrally flowing air collides with the fluid flowing in the annular gap at a rim and blends. The other flange already has an air-liquid mixture, which is completely dissipated by the air flow exiting the outer ring.

One of the drawbacks of internal blown pneumatic nebulizers is that, when the system is idle, the nebulizer space and the outlet are open, which can result in clogging. The resulting malfunctions can be mitigated by external mixers. Liquid dripping of the spray gas from such equipment can only be avoided by a specially designed structure.

The object of the present invention is to provide an atomiser which, when the pressure of the spray medium is reduced or lost, immediately stops the flow of liquid from the atomiser by means of a simple structure;

BACKGROUND OF THE INVENTION The present invention relates to a gas pressure, preferably a compressed air fluid sprayer, a housing, an air and a liquid delivery tube, preferably a threaded pneumatic working cylinder for the housing, a fluid space bounded by a lower, smaller outer diameter portion of the housing and a pneumatic cylinder, above the upper housing housing. connecting air supply pipe. Inlet associated with the housing in the liquid space is a fluid delivery tube, an air space in the interior of the pneumatic cylinder, a valve stem formed in the air space at the end as a piston pin valve, a piston arranged above the air inlet pipe on the stem, a valve stem and a pneumatic cylinder mounted beneath the air inlet tube. ring, in the valve stem is an inclined hole in the ring region. The tapered air nozzle is formed on the underside of the pneumatic cylinder, the detent spacer spaced around the conical air nozzle, the valve stem guide between the valve stem and the pneumatic cylinders, the housing is bottom-closed, preferably threaded, with a bore, pneumatic cylinder. in the pneumatic cylinder, there is a spring arranged between the piston and the closure around the valve stem by inserting a pressure plate.

The invention is illustrated in Figure 1, which is a cross-sectional view of a fluid sprayer.

The housing 1 is connected to the housing by a pneumatic cylinder 2 having a lower part having a smaller outer diameter entering the housing 1 and the inner surface of the housing 1 defining the fluid space. The central part of the pneumatic cylinder 2, at the portion above its housing 1, is connected to the air supply pipe 4, which flows into the air space 5 which forms the inner part of the pneumatic cylinder 2. In the pneumatic cylinder 2, valve valve 6 is arranged, at the top of it the piston 7 above the air supply pipe 4, and sealing sleeve 8, if necessary, to ensure sealing. In the lower part of the valve stem 6 and in the pneumatic cylinder 2 there is the transfer insert 9. The lower part of the pneumatic cylinder 2 is formed as a conical air nozzle 10, which includes a piston needle valve 11 formed at the end of the valve stem when closed. The nozzle 12 is connected to the housing 1 from below by threading. The nozzle 12 includes a bore 13 in which the piston pin 11 fits in the closed position. The liquid delivery tube 14 is connected to the housing 1 to deliver the liquid to be sprayed into the fluid space. The working roller 2 is closed from the top by a screw-threaded connection to the opening pressure adjusting cap 15. The spring 16 is arranged between the piston 7 and the closure 15 on the valve stem 6. A displacement spacer 17 with respect to the axis of the housing 1 is provided between the lower part of the cylinder 2 and the nozzle 12 formed as a conical nozzle. Between the inner wall of the pneumatic cylinder 2 and the valve stem 6, the ring 19 is disposed during the dripping of the air supply tube 4, which separates the air space 5. The valve stem 6 is provided with an inclined bore 18 so that its outlet, its outlet in its closed position, and its inlet are placed in the air space 5 below the ring 19. It is expedient to place the pressure plate 20 between the closure 15 and the spring 16. At the start of the atomizer operation, compressed air is the air supply pipe 4

HU 212 743 lik flows through the pneumatic cylinder 2 and, when the spring 16 is properly adjusted, the piston 11 moves the piston 11 upward until the upper hole 18 of the valve stem 18 is above the ring 2 of the pneumatic cylinder 19; its opening is still in the space under the ring. The air flowing through the bore 18 of the valve stem 6, in the open position of the piston pin 11, sprays the liquid entering the liquid space 3 and transmitted by the spacer 17 on the liquid delivery tube 14. If necessary, the spray cone angle can be increased with the transfer insert 9 in the pneumatic cylinder 2.

The spacer 17 can be replaced by a spiral-shaped groove in the lower part of the housing 1 or in the interior of the nozzle 12. If the anti-slip liquid is susceptible to sticking, it can be blown out of the system by means of compressed air connected to the liquid delivery tube 14 by means of a suitable air valve and pipe system.

Claims (2)

PATENT CLAIMS A gas injector, preferably a compressed air fluid atomizer, with housing, air and fluid inlet pipe, characterized in that said pneumatic cylinder (2), threadedly connected to said housing (1), said housing (1) and said pneumatic cylinder (2). the fluid chamber (3) defined by its smaller outer diameter, the air inlet pipe (4) connected to the upper part (1) of the pneumatic cylinder (2), the fluid inlet pipe (1) connected to the housing (1) 14), the air space (5) in the interior of the pneumatic cylinder (2), the valve stem (6) arranged in the air space (5), in the form of a piston needle valve (11), a piston arranged on the valve stem (6) above the air supply pipe (4) (7), ring (19) between valve stem (6) and pneumatic cylinder (2) located below air inlet pipe (4), in valve stem (6) around ring (19) a bevelled bore (18), a conical air nozzle (10) formed on the lower part of the pneumatic cylinder (2), a spacer spacer (17) arranged around the conical air nozzle (10), the valve stem (6) and the pneumatic cylinder (2) a soldering insert (9) for guiding the valve stem (6), a nozzle (12) for sealing the housing (1), preferably with a thread (13), and a threaded closure (15) for the upper part of the pneumatic cylinder (2) ), the pneumatic cylinder (2) has a spring (16) arranged around the valve stem (6) between the piston (7) and the closure (15), preferably by means of a pressure plate (20). Liquid atomizer according to claim 1, characterized in that the displacement spacer (17) can be replaced by a helical groove milled into the lower part of the housing (1) or into the inner surface of the nozzle (12). HU 212 743 Β Int Cl ⁶ : B 05 B 7/12