NL8402307A - NOZZLE FOR SPRAYING VISCOUS LIQUIDS. - Google Patents

Description

VO 6438

Nozzle for spraying viscous liquids.

The invention relates to a special nozzle for sparingly spraying viscous liquids. The nozzle is particularly suitable for spraying viscous solutions, liquid dispersions, emulsions, suspensions, respectively. sludge connections 3 using compressed air.

Nozzle constructions are usually adapted to a specific area of application, so that the technological parameters of a nozzle, for example spray angle, spray cone shape, droplet size or flow, can only be changed within limited limits.

In known technical methods, liquids for spraying and for obtaining small drops are pressed through nozzles at high pressure. When leaving the mouthpiece, droplets of different sizes (monarial mouthpiece) are formed as a result of relaxation. In other embodiments, low pressure liquids are fed to a nozzle and broken into compressed air, which is passed parallel or perpendicular to the liquid jet (binary nozzle).

Nozzles of this type require high fluid pressure when spraying viscous liquids. When interrupting the spraying process, an additional pneumatic shut-off must be installed to avoid "dripping" of the nozzle.

Due to a special construction of liquid nozzle and air nozzle, it is possible that the liquid is sucked out of the stock reservoir by the exiting compressed air.

25 This nozzle assembly is not suitable for viscous liquids.

U.S. Pat. No. 4,256,263 discloses a monary nozzle designed for high product pressures.

This nozzle is equipped with a swirling device for the liquid to be sprayed, which guarantees an even formation of the spray cone. High viscosity liquids cannot be atomized with this nozzle. Also suitable only for low-viscosity media is a device in which the liquid is introduced laterally into a chamber and mechanically mixed there by means of a ball system, and then exits from the nozzle (U.S. Patent 4,291,835).

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In the US patent directive Re 30 004 a principle is described for viscous liquids which is suitable for low flow rates. However, the liquid is atomized in the form of a hole cone.

S For liquids with very high flow rates, the propellant nozzles described, for example, in U.S. Pat. No. 4,361,282 can be used.

DD-AP 0153 585 discloses an apparatus and a method for developing micro-liquid droplets. A liquid is injected from an opening in an atomizing space in such a way that a substantially high spray cone is formed, which is influenced by an external gas flow, whose flow path runs approximately concentrically and helically with respect to the thought axis of the spray cone, so that the spray cone is broken by the gas flow.

The known devices and methods have the drawback that when spraying viscous liquids (> 500 cp), i.e. in particular liquid dispersions, emulsions, suspensions, respectively. sludge connections, fine droplets are not reached, the run-through layer 20 and the need for air is high. Moreover, with nozzles of known construction, when using viscous liquids, only spray angles less than 90 ° are achieved. There is also the danger that liquid emulsions will be disturbed.

The object of the invention is to develop a nozzle for atomizing viscous liquids by means of compressed air. The nozzle should ensure a high throughput with the smallest possible need for air, avoid disturbances of disperse systems and allow atomization in the form of a full spray cone with the largest possible diameter.

It is the invention. underlying the problem is a nozzle for atomizing viscous liquids, for example liquid dispersions, emulsions, suspensions, etc. to develop sludge connections with which a fine even distribution of the liquid droplets can be achieved at a spray angle of up to 120 ° with a large throughput.

According to the invention, the problem is solved in that by means of a special manner of supplying the liquid to be atomized into a whirl chamber, an intensive premixing of the compressed air with the liquid is obtained such that a spray of the liquid occurs, and the liquid / air mixture 5 is atomized in very fine drops upon expansion of the swirl chamber, notwithstanding the high viscosity of the liquid.

The special manner of supplying the liquid to be atomized is achieved through discharge openings (3) arranged laterally in the conical part of the supply channel (1). The angle at which the outlet openings (3) are disposed relative to the air flow (8) is of particular significance in order to obtain a maximum swirl effect. An angle of 45 ° - 135 ° with respect to the air flow (8) has proved to be favorable.

The compressed air can be brought into the swirling movement in advance in the swirling slots of the known embodiment.

With the nozzle designed according to the invention, a large throughput is achieved with economical atomization. Sparing sputtering is of particular importance with emulsions, since disruption of the dispersion system is avoided. The compressed air requirement for a nozzle 20 according to the invention is considerably smaller compared to known binary nozzles and the technical input compared to monar nozzles is considerably minimized.

Thus, a nozzle designed according to the invention combines the advantages of monar and binary nozzles.

A special advantage of the invention also consists in that the droplet size and the spray quantity are adjusted by changing the number and size of the outlet openings (3) as well as by changing the angle of the outlet openings (3) relative to the air flow (8). could be.

An advantage of the invention furthermore consists in that by the geometrical dimensions of the whirl chamber (4) which can be made variable according to the invention as a result of the change in the distance between liquid outlet (3) and outlet opening of the whirl chamber (9) change of the spray cone to 120 ° is possible (6).

An important advantage over other comparable nozzles is that the spray cone (6) is formed as a complete cone, which guarantees an even droplet distribution.

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Furthermore, the provision of liquid outlet openings (3) in combination with the adjusted liquid and air pressure of the liquid flow after switching off interrupts the liquid transport pump immediately, so that without additional built-in mechanical, electro-magnetic or pneumatic shut-off devices. the spraying process is interrupted and dripping of the nozzle is excluded.

The nozzle system has a special advantage when spraying highly viscous protein or. starch solutions, which form a gel relatively easily, because the use of lower liquid and spray air pressures causes the liquid to cool slightly upon expansion.

Pig. 1 shows a nozzle designed according to the invention for atomizing viscous liquids by means of compressed air.

Compressed air (8) is supplied in a known manner. The liquid to be atomized is guided such that it enters the whirl chamber (4) through 4 outlet openings (3), which are located in the conical part of the central supply channel (1).

In the present example, a high emulsion. viscosity is supplied at a pressure of 0.1 ... 0.2 MPa from the nozzle (2).

The emulsion is pressed in a fine jet into the whirl chamber (4) through the four symmetrically arranged outlet openings (3).

The compressed air (0.2… 0.4 MPa) required by spraying the emulsion is brought into a swirling movement through swirl slots (5). The swirling compressed air mixes with the emitting emulsion in the swirl chamber under high pressure. . A fine mist is formed when leaving the whirl chamber. The spray cone (6) can be changed or replaced by changing the size of the whirl chamber (4). unscrew the union nut (7) to 120 °.

8402307

Claims (2)

1. Nozzle for atomizing viscous liquids, in particular viscous solutions, liquid dispersions, emulsions, suspensions, respectively. sludge connections by means of compressed air, characterized in that a number of outlet openings (3) are arranged in the conical part of the central feed channel (1) for the liquid to be atomized. Nozzle according to claim 1, characterized in that the outlet openings (3) for the liquid to be atomized are arranged at an angle of 45 ° ... 135 ° to the compressed air (8). 8402307