DE29517853U1 - Liquid spray head - Google Patents

Description

The invention relates to a liquid spray head, in particular for high-pressure cleaning and fire extinguishing technology. In such cases, the greatest possible throw distance of the water jet is required with the greatest possible point-like coherence of its jet cross-section. In particular, the pressure energy stored in the jet should remain centered over as great a distance as possible so that in the case of high-pressure cleaning the greatest possible concentrated impact force is available for blasting dirt particles or in the case of fire extinguishing technology the greatest possible impact force is available for so-called "whipping out" flames. The decisive factor is therefore an optimal combination of throw distance and impact force of a jet that is as centered as possible, whereby the droplet size should be as large as possible because then the impact force is again maximized.

High-pressure cleaners are known to press a water volume of e.g. 10-17 l/min through spray nozzles that have such a narrow flow cross-section that a spray pressure of e.g. 80-200 bar is created. Due to the high flow speeds of e.g. 125-200 m/sec, high turbulences occur, which immediately after exiting the nozzle tear open the previously closed flow by forming strong vortices and break it down into tiny water droplets, especially since the decompression of the previously compressed water jet supports this effect. The "pressure energy" contained in the water jet is thus converted into vortex and water droplet formation (formation of droplet surface, which is associated with strong energy withdrawal) as well as the sucking in of ambient air, which is associated with strong braking of the high-pressure jet. The end result of the described effects is that instead of the desired, centered, long-throw point jet, there is a practically strongly braked cone jet with a short throw distance, as can be seen on every point jet nozzle of normal high-pressure cleaners, e.g. at petrol stations. These effects are not fundamentally improved by using other jet nozzles, such as those known from fire extinguishing and irrigation technology. The installation of diffusers or stabilizers in front of the spray nozzle also does not bring about any fundamental improvement, since the described effects in principle remain the same.

There are so-called wet sandblasters in which a point jet nozzle blasts concentrically into a Venturi constriction inlet, so that a vacuum is formed in this blasting chamber, into which sand is sucked through a side opening and then accelerated by the sharp water jet so that abrasion work is possible through the water-sand mixture. Such wet sandblasters produce a certain re-centering of the originally conical "point" jet, but their effectiveness was not sufficient. Attempts were therefore made to carry out a corresponding re-centering using a modified jet concentration head, which, with similar dimensions to the wet sandblaster mentioned, sucks in ambient air through several side holes and re-centers the air-water mixture. However, these systems were also taken off the market due to insufficient effectiveness, as they did not provide sufficient jet improvement, especially in terms of jet concentration and throw distance. Such systems had nozzle bores of d = 1.1-1.5 mm and re-centering bores of D = 7-10 mm. The spray range was only a few meters with a relatively low impact force, while the spray jet continued to expand conically.

The invention aims to improve a concentration head of the latter and known type in such a way that marketable effects are achieved. The invention is therefore based on the object of improving a concentration head of the latter and known type in such a way that spray widths of 5-15 m are achieved with significantly improved jet concentration and significantly increased point impact force, so that working over greater distances is possible for the first time ever. This object is achieved by reducing the ratio of the flow area A = ¹ TfD ² /4 of the re-centering diameter and the flow area a = if d ² /4 of the nozzle diameter d to below A : a = 16. The spray width within the spray head between these two diameters must be approximately dimensioned so that the "cone" jet emerging from the spray nozzle reaches the inlet of the re-centering diameter on the outside and the guide length of the re-centering diameter is approximately designed so that the functions described below are guaranteed or supported.

As a result of this, various surprising effects occur as follows: (1) The water particles that were originally finely atomized after leaving the spray nozzle can reunite in the re-centering area, so that part of the atomization energy used to form the surface is released again and larger drops with a greater flight distance and greater impact force are produced. (2) The strong turbulence of the air-water mixture that occurs after leaving the spray nozzle are greatly reduced by the now larger water drops and their large mass, so that a linearization of the drop trajectories occurs again with the effect of increased flight distance and impact force. (3) The drop surfaces that are reduced as a result of larger water drops suck in less air after leaving the re-centering diameter D, so that the braking of the water drops is reduced and thus again an increased throw distance and an increased impact force.

In a continuation of the inventive idea, the aim is to ensure that the air-water jet does not expand conically after exiting the re-centering diameter, but is somewhat constricted. This task is solved by reducing the ratio of the lateral air suction surfaces to the nozzle bore area a = TYd ² Zb to less than 50. The result of this inventive, independent measure is a somewhat constricted, but by no means expanding jet behind the re-centering diameter D, resulting in a further increase in the flight distance and impact force of the water drops.

In a further development of the inventive concept, the aim is to make the jet cross-section concentrically adjustable . This object is achieved according to the invention in that the re-centering body is arranged axially displaceably on the nozzle carrier. As a result, the nozzle jet in the spray head can be spatially pushed to the re-centering diameter so that
that the latter has only a partial effect or no effect at all in the sense that the jet can emerge unhindered in a conical shape, whereby a considerably larger impact area is created, albeit with a reduced jet width, as in previously known cases.

In a further continuation of the inventive idea, the aim is to further develop the subject matter of the invention as a sandblasting device . This object is achieved according to the invention in that a sandblasting body is arranged on the re-centering body. The latter arrangement can be designed as a single piece or as an assembly structure.

-3-

As a result, there is no longer the difficulty of sand or other granulate having to be fed directly into the almost closed jet within the sandblasting head, which is extremely difficult, but rather it is sucked into the mixed jet which has already been homogeneously dissolved into large droplets, so that not only is the solid particle speed evened out, but also the solid particle distribution is significantly evened out. This in turn results in a significantly evened out abrasion effect. In addition, the re-centering body can be designed as a flat jet body so that wet sandblasting with the flat jet is also possible on the granulate side. In any case, there is the advantage that, as a result of the flight paths already aligned parallel in the droplet flight direction in the re-centering head, the sand/granulate particles are also aligned much better in parallel, so that the considerable abrasion wear on the inner surfaces of the sandblasting head is significantly reduced due to the significantly reduced particle impact effect.

In a further development of the inventive concept, the task is to adjust the concentrated long-throw point jet to a wide jet , in order to enable a sweeping effect over the entire area without changing the working head. This task is solved according to the invention in that an adjusting device which squeezes the jet on both sides is arranged directly behind the re-centering hole in such a way that when not activated, the concentrated long-throw point jet passes through unhindered and when the adjusting device is successively squeezed, the long-throw point jet is increasingly deformed into a flat jet in a manner known per se.

In a further development of the inventive concept, the task is to let the long-throw point jet go back and forth or run on a conical or hypoid shell in such a way that the surface effect of a flat jet or hollow conical jet is achieved in a manner known per se according to the principle of a "turbo nozzle" . This task is achieved according to the invention in that the inventive arrangement of jet body and re-centering body is driven in a manner known per se by a known movement kinematics.

Finally, in a further development of the inventive concept, the task is to combine a first of the functions described above with a second of the functions described above. This task is solved by arranging a changeover valve of a known design in front of the base body of one and the other function - which can also be combined. As a result, the selected function can be controlled separately, so that, for example, even the four functions of long-throw point jet, conical normal point jet, adjustable flat jet and turbo nozzle can be combined without changing the working head, i.e. without any assembly work by simply switching on the nozzle head.

The invention is described below and explained using the figures. They show:

Fig. 1 shows a long-throw point jet head according to the invention with concentric

Beam adjustment and clip-on device at the front;
Fig. 2 a clip-on flat jet adjustment head;
Fig. 3 a clip-on sandblasting head; and
Fig. 4 a double head with gravity changeover valve.

-4-

^w " · W WVVVV

The long-throw point jet head shown in Fig. 1 contains a nozzle body
3, which can be attached to a spray gun or spray lance on the inlet side, for example, using an inlet thread 2. The incoming pressurized water is guided via a stabilizer or diffuser 5 or directly into a Venturi collecting funnel 7 and from there into the nozzle bore 8, from where it jets, expanding slightly conically, into the Venturi collecting funnel 10 and from there into the rectifier bore 11, which is effective when the rectifier body 4 is pulled out to the right (upper half of Fig. 1). Air is sucked in via side bores 9 in order to generate a homogeneous air-water jet with a slight negative pressure so that after it exits the rectifier bore 11, a slight jet constriction takes place, thus counteracting jet expansion. The strong vortices formed in the nozzle bore 8 continue in the mixing chamber, but then lead to intensive mutual contact between the water droplets in the rectifier bore 11, so that the latter combine to form large water drops due to their surface tension, while the rectifier bore 11 simultaneously ensures that the flight paths are aligned parallel. A largely cylindrical, concentric air-water jet 14 with relatively large water particles emerges from the rectifier bore 11, so that spraying can take place relatively far with a small spray jet diameter.

If you want to increase the effective area of the jet, you can push the rectifier body 4 to the left (lower half of Fig. 1). A normal conical jet 13 with an increasing jet cross-section can now form, which, however, naturally has a smaller throw distance than the cylindrical air-water jet. The path of the rectifier body 4 is limited by a stop ring 6, which can also be designed as an O-ring that deforms for assembly.

At the outlet end of the rectifier body 4 there is a bead ring 12, which can be locked into counter-grooves 25, 36 of working heads so that these can easily be plugged onto the long-throw point jet head as shown in Fig. 1, so that when the flat jet adjustable head is plugged on as shown in Fig. 2, a triple function (long-throw point jet, conical adjustable jet, adjustable flat jet) is already achieved. Of course, there are also other fastening options, e.g. using plug-in or screw couplings, and the rectifier body 4 can also be made in one piece with the strip sheet carrier 26, e.g. from plastic.

The adjustment of the flat jet adjustment head according to Fig. 2 is carried out by rotating the rotary housing 28. Then the knobs 20 of the strip sheet carrier 26 slide inwards or outwards on the curved tracks 21, 23, so that the strip sheets 22 are pushed apart to a distance H or together to a distance h, since the flat surfaces 1, 24 prevent the rectifier body 4 from rotating relative to the strip sheet carrier 26. The air-water jet emerging from the rectifier bore 11 thus either passes unhindered through the height H or is pressed through the forced slot with a height h, so that in the latter case a flat jet is produced. The strip sheet carrier

26 and the rotary housing 28 can be axially connected, e.g. with a bead-groove connection

27 must be secured against each other.

The sandblasting head shown in Fig. 3 can also be attached to the long-throw point jet head according to Fig. 1. It is driven by the cylindrical air-water jet 14, 31, which contains aligned trajectories of large, low-swirling water drops.

This allows the granulate to enter this jet easily, whereas entry into a conventional * point jet within the sandblasting head with strongly swirling, small water droplets and different speed distribution along the cross-sectional diameter does not result in a uniform granulate speed and thus a wide variety of impact effects. The large water droplets also result in a significantly improved energy transfer to the granulate, so that the abrasion effect also increases in absolute terms. The water paths 34 and granulate 35 in Fig. 3 have been optically pulled apart purely to simplify the drawing. In reality, it is a homogeneous mixture.

The switching head shown in Fig. 4 contains a pressurized water connection 41 in the housing 42. The ball 43 falls in front of the lower ball seat screw bushing 44 so that only the upper working head can work. As an example only, a long-throw point jet head 45 is shown (above) together with a turbo nozzle 46 (below). In this arrangement, a 4-fold working function can be achieved without changing the working head, provided that the long-throw point jet head already contains the three working functions described.

It goes without saying that the rectifier body 4 can be secured against rotation relative to the nozzle body 3 - e.g. by means of a pin located in one component that engages in an axial slot in the other component. In this case, the adjustment of the point jet 14 to the cone jet 13 on the one hand and the adjustment of the flat jet according to Fig. 2 on the other hand become independent of one another.

It is understood that the side bores 9 can be closed or opened differently, e.g. by means of an axially displaceable closure bushing or otherwise, so that different beam concentrations can be set.

The advantages that can be achieved with the invention are that it significantly improves a wide variety of effects (long throw, impact force, adjustability, sandblasting) or even makes them possible in the first place. This means that the effect of considerably larger and more expensive pumps can be achieved much more cost-effectively or even made possible in the first place using simple means.

-6-

Claims (1)

Protection claims Liquid spray head, in particular for use in high-pressure cleaning and fire extinguishing technology, with a nozzle body 3 receiving the pressure fluid and a rectifier body 4 sprayed internally by the latter, characterized in that the ratio of the flow-through areas of the rectifier bore 11 and the nozzle bore 8 is less than 16. Liquid spray head, particularly for use in high-pressure cleaning and fire extinguishing technology, with a nozzle body 3 receiving the pressure fluid and having side openings 9, as well as a rectifier body 4 irradiated from the inside by the latter, characterized in that the ratio of the total area of the side openings 9 to the area of the nozzle bores 8 is less than 50. Liquid spray head according to one of claims 1 or 2, characterized in that the rectifier body 4 is arranged axially displaceably on the nozzle body. Liquid spray head according to one of claims 1 to 3, characterized in that a sandblasting head is connected downstream of the rectifier body 4. Liquid spray head according to one of claims 1 to 3, characterized in that the rectifier body. 4 is followed by an adjusting device which can narrow the through-flow jet in such a way that in one adjusting position the jet passes through unhindered and in the other adjusting position the jet has to pass through a slot. Liquid spray head according to one of claims 1 to 3, characterized in that the cylindrical air-water jet is moved back and forth so that it forms a flat jet in a manner known per se. Liquid spray head according to one of claims 1 to 3, characterized in that the cylindrical air-water jet is moved on a conical or hypoid shell in such a way that it forms a hollow cone or hollow hypoid in a manner known per se. Liquid spray head according to one of claims 1 to 3, characterized in that the side openings 9 can be partially or completely closed by a closing device. Liquid spray head according to one of claims 1 to 3, characterized in that the nozzle body 3 and the rectifier body 4 are secured against rotation. Liquid spray head according to one of the preceding claims, i.e. that two different working heads are arranged in a manner known per se on a switching valve so that only one working head sprays at a time.