DE19918120A1 - Atomizer jet for dispensing fluid, with disk-shaped helical element upstream of outlet aperture - Google Patents

Abstract

The atomizer has a jet body (1) with an internal boring (2) which has an internal thread (5). An insert body (6) extends along the longitudinal axis (3) of the jet, and a downstream outlet aperture (4). Upstream of this aperture there is a disk-form helical element (25) to improve the atomizing and preparation of the fluid for spraying.

Description

State of the art

The invention relates to an atomizer nozzle according to the Genus of the main claim.

Fine atomizer nozzles are already from the catalog "Nozzles and Industrial accessories "Catalog D 51 M from 1995 of the company Spraying Systems Deutschland GmbH known. This catalog can already be seen in chapter F (page F9) that it is for it makes sense to provide nozzles for special applications, where a fluid swirled or swirled becomes. It is therefore suggested in the catalog Spray drying nozzles that have an inner insert body have one at its downstream end Owns vertebral head. The conical vertebral head has one or several swirl channels on the outer contour in the form of Grooves or slots are made.

Advantages of the invention

The atomizing nozzle according to the invention with the characteristic Features of the main claim has the advantage of being on particularly simple and inexpensive to manufacture is. The atomizer nozzle is particularly on hers  downstream end simple and yet very precise mountable. They can be produced in very large numbers Disc-shaped swirl elements according to the invention in always produce exactly reproducible way. Opposite the Manufacture of insert bodies with their exact The outer contour shaped swirl generating means are disc-shaped swirl elements in the manufacture cheaper.

The disc-shaped swirl element is very simple structured and therefore easy to shape. The Swirl element has the task of To produce rotary motion in the fluid to be atomized. Because it the swirl element is a single component, do not occur when handling it in the manufacturing process Restrictions on. Compared to insert bodies that their outer contours grooves or similar swirl-generating Have depressions in the swirl element an inner opening area is created by the simplest means be that over the entire axial thickness of the Swirl elements extends and from an outer circumferential Edge area is surrounded.

By the measures listed in the subclaims advantageous developments and improvements in Main claim specified atomizer nozzle possible.

The swirl element can be easily clamp between the insert body and the nozzle body. Advantageously, the swirl element with the Insert body are slightly crushed, which the Flow cross section of the swirl channels changed very easily can be. In this way, the flow coefficient of the Nozzle can be adjusted.  

The disk-shaped swirl element is advantageous to be conical. The flow gets this way already axial when flowing into the outlet opening Speed component. Because of this, the Atomization can be further improved. Another advantage is that due to the frustoconical contours of nozzle body and insert body a very load-stable atomizer nozzle is present.

drawing

Embodiments of the invention are shown in simplified form in the drawing and explained in more detail in the following description. In the drawings Fig. 1 shows a first embodiment of a spray nozzle, Fig. 2 a in the atomizing nozzle according to FIG. 1 used swirl element, Fig. 3 shows another embodiment of a swirl element, Fig. 4 shows a second example of a spray nozzle, and Fig. 5 a in the atomizing nozzle of FIG. 4 used swirl element.

Description of the embodiments

The atomizer nozzle shown by way of example in FIG. 1 has a nozzle body 1 which forms the housing of the nozzle. The nozzle body 1 has an inner bore 2 , which extends concentrically to a longitudinal axis 3 of the nozzle. The fluid to be atomized is passed through the bore 2 , namely up to an outlet opening 4 formed in the nozzle body 1 at the downstream end of the atomizer nozzle.

The nozzle body 1 has an internal thread 5 on the wall of the bore 2 . An insert body 6 is fastened in the bore 2 by screwing it in and has an external thread 7 at least over an axial section. On an upstream end face 8 of the largely cylindrical insert body 6 , assembly aids 9 are provided which enable the insert body 6 to be easily installed in the nozzle body 1 with a screwing tool, not shown. The bore 2 is designed in such a way that a recess 11 adjoins the internal thread 5 in the downstream direction and has a larger diameter than the bore 2 in its other areas and thus forms an annular space. From the recess 11 , the bore 2 runs as a cylindrical section 12 until it ends at a flat shoulder 13 running perpendicular to the longitudinal axis 3 of the nozzle.

The outlet opening 4 , which is formed about the longitudinal axis 3 of the nozzle, extends from this shoulder 13 and is thus still in direct connection with the bore 2 . The outlet opening 4 has two axially successive regions, on the one hand a frustoconically tapering region 14 and on the other a cylindrical region 15 . An external thread 18 is provided on the nozzle body 1, for example, for fastening the atomizer nozzle in a nozzle receptacle. A screw connection that can be produced with the aid of the external thread 18 represents only one of the possible types of fastening of the atomizing nozzle.

At least in the axial extent of the external thread 7 , the insert body 6 has an inner longitudinal bore 19 which is designed as a blind hole. To guide the fluid to be sprayed from the inner longitudinal bore 19 in the direction to the outlet opening 4, in the insert body 6 at least one transverse opening 20 is formed. This at least one transverse opening 20 connects the inner longitudinal bore 19 to the outer circumference of the insert body 6 . The at least one transverse opening 20 is arranged such that it opens into the bore 2 in the area of the recess 11 . The outer contour of the insert body 6 is largely cylindrical, but has one or more flats 22 at least in the area of the one opening transverse opening 20 or, in the case of several transverse openings 20, in the corresponding areas. In this way, at least one axially extending flow channel 23 is formed between the wall of the cylindrical section 12 and the at least one flat 22 on the insert body 6 .

At its downstream end, the insert body 6 has an end face 24 with which the insert body 6 rests on a disk-shaped swirl element 25 according to the invention. In order to enable a reliable inflow of the fluid from the at least one flow channel 23 into the swirl element 25, the insert body 6 is formed with a beveled section 26 at the transition from the cylindrical section to the end face 24 . The end face 24 can be designed as a flat surface or, for example, have a central conical section 27 , as can be seen in FIG. 1. In the latter case, the cone section 27 serving to guide the flow extends through an inner opening region 30 of the swirl element 25 and projects into the frustoconical region 14 of the outlet opening 4 .

The insert body 6 is introduced axially into the bore 2 to such an extent that the insert body 6 fixes the swirl element 25 with its end face 24 . The swirl element 25 is thus firmly clamped between the end face 24 and the shoulder 13 of the nozzle body 1 , on which the swirl element 25 rests. The axial clamping force is generated in the embodiment of Fig. 1 via the screw thread 5/7. The insert body 6 can also be fastened in the nozzle body 1 by pressing, caulking or in some other way.

The atomizer nozzle is always open Nozzle function. Corresponding is one Atomizer nozzle either a valve or a pump upstream, through which the fluid to be atomized provided. The fluid supply is also corresponding to the atomizer nozzle stopped by a valve or a pump.

FIG. 2 shows a swirl element 25 clamped between the end face 24 of the insert body 6 and the shoulder 13 of the nozzle body 1 as a single component in a top view. The swirl element 25 can be produced inexpensively, for example by means of stamping, wire EDM, laser cutting, etching or other known methods from a sheet metal or by means of electrodeposition. In the swirl element 25, an inner opening portion 30 is formed which extends over the entire axial thickness of the swirl element 25th The opening area 30 is an inner swirl chamber 31 through which z. B. the conical section 27 of the insert body 6 extends through, and formed by one or a plurality of swirl channels 33 opening into the swirl chamber 31 . The swirl channels 33 open tangentially into the swirl chamber 31 and, with their ends 34 facing away from the swirl chamber 31, are not connected to the outer circumference of the swirl element 25 . Rather, a peripheral edge region 35 remains between the ends 34 of the swirl channels 33 designed as inlet pockets and the outer circumference of the swirl element 25 .

Due to the tangential confluence of the swirl channels 33 in the swirl chamber 31 , the fluid receives an atomizing impulse which is retained up to the outlet opening 4 . Due to the centrifugal force, the fluid is sprayed out in a hollow cone at a large spray angle. The ends 34 of the swirl channels 33 serve as collecting pockets, which form a large-area reservoir for the low-turbulence inflow of the fluid. After the flow deflection, the fluid enters the actual tangential swirl channels 33 slowly and with little turbulence, as a result of which a largely trouble-free swirl can be generated.

The swirl element 25 is only described in more detail in an advantageous embodiment with reference to FIG. 2; disk-shaped swirl elements 25 with opening areas which differ significantly from the opening area 30 shown in FIG. 2 are also conceivable. In addition to the swirl chamber 31 and a few swirl channels 33 , the swirl element 25 must have material areas that secure the swirl element 25, for example. B. allow by clamping or clamping.

FIG. 3 shows a swirl element 25 which has only a single swirl channel 33 . The swirl channel 33 opens tangentially into the inner swirl chamber 31 , which is largely circular. The end 34 of the swirl channel 33 facing away from the swirl chamber 31 is of widened design in order to ensure a low-turbulence inflow of the fluid. In contrast to the swirl element 25 shown in FIG. 2, the one swirl channel 33 of the swirl element 25 according to FIG. 3 is connected to the outer circumference of the swirl element 25 , so that there is no edge region 35 on the swirl channel 33 .

In the second exemplary embodiment of an atomizer nozzle according to FIG. 4, the parts that are the same or have the same effect as the exemplary embodiment shown in FIG. 1 are identified by the same reference numerals.

The embodiment according to FIG. 4 differs from that according to FIG. 1 in that the disk-shaped swirl element 25 is not conical, but is conical. From the contour of the opening area 30 , the swirl element 25 can correspond to the opening area 30 according to FIG. 2. The desired contour of the opening area 30 can be introduced into a prefabricated conical sheet metal bowl, for example by means of punching. The swirl element 25 is clamped in the spray nozzle between a formed in place of the step 13 extending frustoconical inner surface 37 of the nozzle body 1 and a likewise frustoconical extending outer surface 38 of the insert body 6 at its downstream end. The axial clamping force is generated in the example shown on the screw thread 5/7. In order to ensure a uniform inflow of the fluid into the swirl channels 33 of the swirl element 25, the insert body 6 is designed such that it is spaced downstream of the recess 11 from the wall of the cylindrical section 12 of the nozzle body 1 . In this way, an annular flow channel 23 is created .

In FIG. 5, a swirl element 25 clamped between the frustoconical inner surface 37 of the nozzle body 1 and the likewise frustoconical outer surface 38 of the insert body 6 is shown as a single component in a perspective view.

Similar to the frustoconical inner surface 37 and outer surface 38 , the inner surface 37 of the nozzle body 1 and the outer surface 38 of the insert body 6 can also be hemispherical or generally spherical in order to form a z. B. dome-shaped swirl element 25 between them.

The atomizer nozzles described are suitable for. B. as Paint nozzles, for use with inhalers, at Freeze-drying process, for (heating oil) burners, for removing or Injecting liquids, such as B. drinks to Atomizing drugs, liquids in the Agriculture or chemical industry.

Claims (11)

1. atomizer nozzle for dispensing a fluid with a nozzle body ( 1 ), with a longitudinal axis ( 3 ), with an insert body ( 6 ) extending along the longitudinal axis ( 3 ) and fastened in the nozzle body ( 1 ) and with a downstream outlet opening ( 4 ), characterized in that a disk-shaped swirl element ( 25 ) is arranged upstream of the outlet opening ( 4 ). 2. Atomizer nozzle according to claim 1, characterized in that the nozzle body ( 1 ) upstream of the outlet opening ( 4 ) has a shoulder ( 13 ) running perpendicular to the longitudinal axis of the nozzle ( 3 ) and the insert body ( 6 ) has a lower end face ( 24 ) and the swirl element ( 25 ) is clamped between the end face ( 24 ) and the shoulder ( 13 ). 3. Atomizer nozzle according to claim 1, characterized in that the swirl element ( 25 ) is conical. 4. Atomizer nozzle according to claim 3, characterized in that the nozzle body ( 1 ) upstream of the outlet opening ( 4 ) has a frustoconical inner surface ( 37 ) and the insert body ( 6 ) has a frustoconical outer surface ( 35 ) and the swirl element ( 25 ) between the outer surface ( 38 ) and the inner surface ( 37 ) is clamped. 5. Atomizer nozzle according to one of the preceding claims, characterized in that the swirl element ( 25 ) has an inner opening region ( 30 ) with at least one swirl channel ( 33 ) which extends completely over the entire axial thickness of the swirl element ( 25 ), the or the swirl channels ( 33 ) are not connected to the outer circumference of the swirl element ( 25 ) by a peripheral edge region ( 35 ). 6. Atomizer nozzle according to one of claims 1 to 4, characterized in that the swirl element ( 25 ) has an inner opening region ( 30 ) with a swirl channel ( 33 ) which extends completely over the entire axial thickness of the swirl element ( 25 ), wherein the swirl channel ( 33 ) is connected to the outer circumference of the swirl element ( 25 ). 7. Atomizer nozzle according to claim 5 or 6, characterized in that the inner opening region ( 30 ) of the swirl element ( 25 ) can be shaped by means of punching. 8. Atomizer nozzle according to claim 5, characterized in that the inner opening region ( 30 ) is formed by an inner swirl chamber ( 31 ) and by a plurality of swirl channels ( 33 ) opening into the swirl chamber ( 31 ). 9. atomizer nozzle according to claim 8, characterized in that the swirl channels ( 33 ) open tangentially into the swirl chamber ( 31 ). 10. Atomizer nozzle according to claim 8 or 9, characterized in that the swirl channels ( 33 ) from the swirl chamber ( 31 ) have distant ends ( 34 ) which, as inlet pockets, have a larger cross section than the actual swirl channels ( 33 ). 11. Atomizer nozzle according to claim 1 or 2, characterized in that a conical section ( 27 ) is formed on the insert body ( 6 ) which projects through an inner opening region ( 30 ) of the swirl element ( 25 ).