DE19506003A1 - Single jet nozzle - Google Patents

Description

The invention relates to a single-jet nozzle which is attached to sanitary water basins, can be used especially in so-called whirlpools. The jet nozzle is made of different Sources with liquid and gaseous medium can be supplied, both media individually or as Mixture can be ejected into the interior of a water basin.

Single-jet nozzles are known which can be supplied by a source which supplies a fluid flow, or which are supplied with liquid from a water basin in the flow circuit. In which in the case of circular operation, supply lines are provided which have at least one the interior of the water basin in fluid communication and have a water circulation pump. Known jet nozzles are for the purpose of Aeration of the water steel can be supplied with air, the air either according to the principle of Water jet pump or the "reverse" water jet pump, or by a compressed air generating blower accelerated via the supply lines provided for the jet nozzle is feedable.

These known jet nozzles are water and air or a mixture of water and air can be jetted into the interior of the pool filled with water, with a revitalization and ventilation of the water in the interior of the pool can be achieved. That or the inflowing media form an aerated jet stream for exercise an underwater massage can be used.

With such jet nozzles, it is desirable to determine the directional orientation of the delivery jet to change. For this purpose, according to US 3,905,538, a pivotable one was proposed Ball nozzle, the spherical surface of which is adjustably supported in a ring-like holding device is, with a central bore penetrating the ball nozzle as a jet pipe and as an outlet opening serves. By swiveling the ball nozzle, the directional orientation of the delivery jet is influenceable.

From EP 290 476 a jet nozzle is known, the one in the interior of the water basin opening outlet a baffle plate is placed in such a way that the exit direction of the or the flowing media is deflected radially outwards.

These have different steel nozzles used in so-called whirlpools the disadvantage that the baffle plate as a large-scale device on the floor and the seat the whirlpool is provided. A decisive disadvantage is that the radial outside the cover plate emittable medium jet as a result of the mass acceleration Horizontal flow spreads at the bottom of the pool, then favored by the Buoyancy of the air contained in the jet flow on the side walls of the whirlpool to ascend vertically. The disadvantage of this jet nozzle can be seen in particular in that the user of such a whirlpool from the substantially horizontal Jet flow is not flowable. The ascending ones on the side walls of the whirlpool Air components hardly contribute to an effective underwater massage. So far is with this Jet nozzle at best near the side walls "ventilation" of the pool water content possible. Such jet nozzles can be successfully used as ventilation devices in Bioreactors, for wastewater, clarification and putrefaction tanks. This variant is for whirlpool operation a single jet nozzle less suitable.

The object of the invention is to design a single-jet nozzle compared to the known types, where the use is more versatile and convenient and where the Directional orientation of the delivery jet in a simple but also automatable way is changeable.  

This object is achieved according to the invention in that one from a source with one liquid medium supplyable jet nozzle, the outlet mouth, which acts as an annular gap nozzle is formed, a beam adhesive wall and one in flow communication with the atmosphere standing and ventilable second supply nozzle, which preferably also as an annular gap nozzle is formed, is assigned which second supply nozzle between the mouth of the Annular gap nozzle and the jet adhesive wall opens, the directional orientation of the Dispensing jet due to supply (ventilation) of the second supply nozzle can be influenced.

In the embodiment, the single-jet nozzle according to the invention has supply channels for the supply of water and air, which supply channels are arranged essentially coaxially to one another, at least in the vicinity of their medium outlet openings. The respective medium outlet opening of both supply channels is designed as an annular gap nozzle, an outer annular gap nozzle concentrically surrounding an inner annular gap nozzle,
in a first embodiment variant according to the invention,
in the center of the inner annular gap nozzle there is a jet adhesive wall, which is preferably designed as a cone, but at least as a circular cone, the walls of the outer annular gap nozzle forming the outflow channel having a wall section running obliquely towards the center,
and downstream of both annular gap nozzles there is provided an inwardly curved conical ring wall which is at least designed as a blunt circular cone, the inner wall of which forms a flow channel which has a collecting nozzle near the annular gap nozzles and a central outlet nozzle downstream,
in a second variant,
the walls of the inner annular gap nozzle that form an outflow channel have a wall section that extends obliquely to the radially outward, and a radially conical, at least conical beam-retaining wall comprising the outer annular gap nozzle is formed radially outside of the outer annular gap nozzle.

The embodiment of the invention with the first variant has the advantage that when the outer annular gap nozzle with a liquid medium this from the central outlet nozzle is deliverable and that with simultaneous supply to the outer annular nozzle with water and inner annular gap nozzle with air, a water / air mixture can be generated, which radially outside the Ring wall is deliverable.

In the embodiment according to the invention, the directional orientation of the delivery jet is through the supply (ventilation) of the inner annular gap nozzle can be influenced.

The invention is further improved if the ring wall is spaced from another outer jacket wall is surrounded, the outer wall of the ring wall and the inner Wall of the jacket wall form a flow channel. Both open into the flow channel Annular gap nozzles. Through the flow channel is a mixture consisting of two ring jet nozzles dispensable media, broadcastable.

In a preferred embodiment, on the wall that separates the supply channels, Area of the outlet opening of the water-conducting annular gap nozzle in the water-guiding flow channel is formed into the edge.

This configuration makes switching the beam orientation easier, so that the The directional orientation is influenced by simple ventilation of the delivery jet.

A further improvement of the invention can be achieved if at the center of the frustoconical ring wall opens another air supply line.  

This configuration has the advantage that larger amounts of air in the interior of the Water basin can be irradiated. The air intake is increased when the Air supply line can be supplied by a compressed air generating blower and with compressed air is applied.

It is advantageous that the frustoconical approach adjoining the inner annular gap nozzle Form the beam wall in such a way that this with its approach height the mouth of the outer Annular gap nozzle slightly protrudes or slightly protrudes into the flow channel.

The invention undergoes a further improvement if the frusto-conical ring wall is axial is slidable and as a partition to close to the mouths of the two Annular gap nozzles can be brought up. Also a device which can be actuated by rotation and which has a Axial displacement of the ring wall enables is provided within the scope of the invention.

This configuration has the advantage that when the outer annular gap nozzle is supplied with water, the water can also be dispensed via the outer jacket of the frustoconical ring wall. All that needs to be done is to push the ring wall axially close to the annular gap nozzle.

The design of at least one annular gap nozzle with webs which define the circumferential annular gap interrupt and divide the annular gap nozzle into individual nozzle segments has the advantage that each nozzle segment can be individually supplied (ventilated). It is envisaged that the circular Arc length of a nozzle segment is limited by two webs.

It should be noted that the outlet openings of the individual, nozzle segments are also round or can have oval supply openings. In this respect, the term "annular gap nozzle" in to understand the broadest sense.

The invention can be further developed in that the on the inner annular gap nozzle trained nozzle segments, individually via provided external supply channels are available. This configuration has the advantage that the individual nozzle segments can be supplied and acted upon differently, means being provided by which the supply current can be interrupted and the flow can be controlled.

This configuration has the advantage that the nozzle nozzles formed on the inner annular gap nozzle Segments can be supplied or acted upon individually or together or alternately with air are. By supplying (ventilation) the various nozzle segments of the inner Annular gap nozzles are corresponding partial areas of what can be dispensed from the outer annular gap nozzle Water jet can be aerated and its directional orientation can be influenced.

In the further development it is provided that the individual nozzle segments alternately together or to supply air individually, this can be done with suction air or compressed air.

The comfort achievable with the invention is further increased if the ventilable Annular gap nozzle or their individual nozzle segments can be pressurized with compressed air, such as this will be described below.

The free cross sections of the supply channels are preferably in the region of their Outlet mouths arranged at a relative angle less than 120 °.

The second embodiment variant has the advantage that when the inner annular gap nozzle is supplied with Water this on an intended sloping radially extending channel section flowing medium deflectable radially outward and radially deflected into the interior of the Water basin is dispensable. With simultaneous supply of air to the outer annular gap nozzle a mixture of water and air can be generated and funnel-shaped into the interior of the Water basin dispensable.

The previously described design variants for the supply (ventilation) of the Annular gap nozzle and its division into individual nozzle segments is also here for these  described second variant applicable, the directional orientation of the delivery beam, such as previously described, by the supply (ventilation) of the now outer Annular gap nozzle is changeable.

In the further embodiment of the invention, is provided for both variants Air supply line (s) to be pressurized with compressed air, the air supply line from a compressed air generating blower connected in flow can be acted upon, the fan preferably being operable with electrical energy and provided by means of electronic means, both in continuous operation, such as power adjustable, and in interval operation is operable.

Further advantages of the invention are the following description, the claims and the Removable drawings.

Fig. 1 shows in a sectional view:
A jet nozzle 1 with a nozzle housing, which is anchored in a stationary manner in a mounting opening of the pool wall by means known per se or is designed as a flexible device. The nozzle housing is connected and can be supplied by the supply line 2 for water and 3 for air with several fluid-supplying sources Q 1, Q 2, etc.

Supply channels are formed within the nozzle housing, the supply channel 4 essentially axially passing through the nozzle housing and having an annular gap nozzle 5 on the end face.

The supply channel 6 is arranged essentially coaxially with the supply channel 4 and has an annular gap nozzle 7 on the end face.

The channel walls forming the free cross section of the supply channels 4 , 6 are arranged in the region of their outlet openings at a relative angle of less than 120 °.

The walls forming the outflow channel 22 of the outer annular gap nozzle have a wall section 28 which runs obliquely towards the inside.

The supply channel 4 has on its outside 8 a radially conical, but at least circular cone-shaped beam adhesive wall 9 on the outside of its cross section, which essentially covers its cross section.

In a preferred embodiment, a further supply channel 10, which is in flow connection with the source Q _3, passes through the supply channel 4 centrally inside and opens downstream of the inner annular gap nozzle 5 in the center of the conical or at least circular cone-shaped jet adhesive wall 9 with a central outlet opening 11 .

Arranged downstream of the annular gap nozzles 5 and 7 is an obtuse-ended conical shape, but at least an obtuse-ending circular cone-shaped annular wall 12 . The annular wall 12 has a collecting nozzle 13 near the annular gap nozzles 5 and 7 and, downstream, in the region of the central outlet opening 11 , an outlet nozzle which forms an annular nozzle 14 with the outlet opening 11 . The ring nozzle 14 and the outlet opening 11 are preferably coaxial, but offset from one another at the height of their outlet openings.

In an advantageous embodiment, the annular wall 12 is designed to be axially displaceable. Such displaceability can be designed by means of a sled-skid-like guide device (not shown) which on the one hand has an end stop and on the other hand is anchored to the housing of the single-steel nozzle 1 . The ring wall 12 is axially displaceable on the device or rotatably mounted in the event of an axial displacement.

The arrangement of an outer circumferential jacket wall 15 is advantageous, which surrounds both the outer annular gap nozzle 7 and the annular wall 12 and thereby forms a flow channel 16 .

The approach 31 to the mouth of the inner annular gap nozzle 5 of the jet adhesive wall 9 is designed such that it slightly projects beyond the mouth of the outer annular gap nozzle 7 or protrudes into the flow channel formed between the jet adhesive wall 9 and the annular wall 12 .

However, it is also possible to design the adjacent extension 31 on the wall provided between the channels 4 and 6 , namely near the mouth of the outer annular gap nozzle 7, in such a way that the extension projects into the water-conducting channel 6 with one edge.

This essential detailed design is illustrated again in FIG. 1a.

The flow pattern of a water jet that can be emitted from the outer annular gap nozzle is represented by arrows. In the left half of the illustration, the inner annular gap nozzle is supplied (ventilated) and in the right half the inner annular gap nozzle is not supplied. In the latter case, the water jet can be aerated downstream at the outlet opening 11 .

The free cross sections of the supply channels 4, 6 are arranged in the region of their outlet openings at an angle of less than 120 to one another.

Fig. 2
1 shows a preferred design variant of a single-jet nozzle according to FIG. 1.

The inner annular gap nozzle 5 is divided by webs 17 , 18 (visible in FIG. 4) into individual nozzle segments which interrupt the annular gap nozzle, each nozzle segment being assigned its own supply channel 19 , 20 .

As a special variant, the supply duct 20 is provided with an inlet opening 21 arranged downstream and can be supplied (ventilated) from the downstream. A plurality of nozzle segments of the annular gap nozzle can be in flow connection through flow channels 20 provided with downstream inlet openings 21 and can be supplied from downstream. The nozzle segments of the annular gap nozzle which can be supplied downstream can be operated as a multivibrator due to pulse feedback.

The supply channel 19 leads to the outside and is in flow connection with a source Q₂, from which source the respective nozzle segment of the annular gap nozzle can be supplied. A plurality of nozzle segments of the annular gap nozzle 5 are preferably in flow communication with a source (as shown in FIG. 4) via supply channels 19 leading to the outside and can be supplied by this source.

The nozzle segments, which can be supplied from the outside, can be operated as a multivibrator if they are from an impulsive source can be influenced or supplied.

Fig. 3
Shows a section through the second variant of the single jet nozzle according to the invention.

In contrast to the first variant ( FIGS. 1 and 2), the inner annular gap nozzle 5 has an outflow channel 22 pointing radially outwards. The outer annular gap nozzle 7 now has webs 17 , 18 and the supply (ventilation) devices, as described above for FIG. 2. Radially outside of the outer annular gap nozzle 7 is a substantially conical beam adhesive wall 23 comprising the annular gap nozzle 7 , with an outward slope, the beam adhesive wall having a protruding edge 32 formed by its inner diameter, which edge in height slightly overlooks the mouth of the inner outflow channel 33 and tangentially touches the beam angle a of the inner annular gap nozzle.

Arrows in the right half of the illustration show the flow profile of a water jet that can be emitted from the inner annular gap nozzle 5 , the outer annular gap nozzle 7 not being supplied (aerated).

In the left half of the illustration, the flow profile of a water steel discharged from the inner annular gap nozzle 5 is shown, the outer annular gap nozzle being supplied (aerated).

The inner boundary wall 24 of the inner annular gap nozzle 5 is preferably formed by an element 25 , which on its side 26 facing the interior of the water basin is essentially flat to slightly arched and into an opening opening the inner annular gap nozzle and a position closing the inner annular gap nozzle by axial means Stroke or stroke rotary movement is movable. The element 25 can preferably be moved into its open position by the pressure of the flowing medium and can be moved hydrostatically or with the aid of a closing spring into its closed position.

The element 25 is anchored to a holding device 27 , which is fastened within the supply channel 2 , at least axially movable and anchored by a screw thread. The element 25 is preferably always loaded in the closed position by a closing spring supported on the holding device. In an advantageous development, the movable element 25 is designed as an exchangeable valve device and can be fixed in a watertight manner as a replaceable component in a recess 29 provided within the nozzle housing. The design of such a recess 29 is shown by a dashed line.

The free cross sections of the supply channels 4 , 5 are arranged in the region of their outlet openings at a relative angle of less than 120 °, but greater than 25 ° to one another.

The design referred to as protruding edge 32 can of course also be formed on the wall separating the inner and outer ring nozzles from one another, this protruding edge being formed all around, jumping radially inwards into the water outflow channel.

This essential design feature is illustrated again with FIG. 3a.

Fig. 4
FIG. 4 shows, seen from the interior of Beck, fragments of the jet nozzle according to FIG. 1 and 2. The reference numerals used are used in accordance with again.

In this figure, the "webs" 17 , 18 described above are shown visibly. A nozzle segment 30 is formed in each case between two webs delimiting the circular arc length of a nozzle segment.

Each nozzle segment 30 (a, b, c, d) is connected by its own supply channel 19 (a, b, c, d) (dashed line) to a source Q or to different sources Q₁, Q₂, Q₃ and can be supplied ( ventilated). The means required for the supply of liquid medium are not shown in this figure, but they result from the consideration of FIGS. 1 to 3.

Reference list

1 jet nozzle
2 water supply line
3 Air supply line
Q source (Q₁, Q₂ etc.)
4 supply channel for water
5 inner annular gap nozzle
6 Air supply duct
7 outer annular gap nozzle
8 end face
9 beam adhesive wall
10 air supply duct
11 outlet opening in the center of the jet trap 9
12 ring wall
13 collecting nozzle
14 ring nozzle
15 outer ring jacket wall
16 flow channel
17 bridges
18 bridges
19 supply channel
20 supply channel
21 entrance opening
22 outflow channel
23 beam adhesive wall
24 boundary wall
25 axially movable element
26 facing the interior
27 holding device
28 wall section
29 recess
30 nozzle segments
31 adjacent approach
32 protruding edge
33 mouth of the inner inflow channel

Claims (23)

1. jet nozzle ( 1 ) which can be connected to a source (Q), which jet nozzle has an annular gap nozzle ( 7 ) as an outlet opening, which annular gap nozzle can be supplied with a liquid medium from the source (Q), the annular gap nozzle ( 7 ) being a A jet wall ( 9 ) and a ventilable second supply nozzle ( 5 ) which is in flow communication with the atmosphere and is connected to the atmosphere via at least one supply channel ( 6 , 19 ), which second supply nozzle ( 5 ) is located between the mouth of the annular gap nozzle ( 7 ) and the jet adhesive wall ( 9 ) opens out and the walls of the annular gap nozzle ( 7 ) forming the outflow channel ( 22 ) have a wall section ( 28 ) which runs obliquely inwards towards the center, the directional orientation of the discharge jet being aerated by the supply nozzle ( 5 ). can be influenced. 2. single jet nozzle (1), which is connectable to a source (Q), which has single jet nozzle as an annular nozzle outlet opening (5), which annular gap nozzle (5) is supplied with a liquid medium from the source (Q), wherein the annular gap nozzle ( 5 ) a jet adhesive wall ( 23 ) and a ventilable and for the purpose of ventilation, via at least one supply channel ( 19 ) with the atmosphere in flow communication with the second supply nozzle ( 7 ) is assigned, which supply nozzle ( 7 ) between the mouth of the annular gap nozzle ( 5 ) and the jet adhesive wall ( 23 ) opens out and the annular gap nozzle ( 5 ) has an obliquely radially outward wall section ( 28 ), the directional orientation of the dispensing jet being able to be influenced by ventilation of the supply nozzle ( 7 ). 3. jet nozzle ( 1 ) from a source (Q) of a liquid medium and from at least one source (Q₁, Q₂, Q₃) of a gaseous medium can be supplied, which jet supply channels ( 4 , 6 , 19 ) for the supply of water and of air, which supply channels are arranged substantially coaxially with one another at least in the vicinity of their medium outlet openings and the respective medium outlet openings of the supply channels are designed as annular gap nozzles ( 5 , 7 ), an outer annular gap nozzle ( 7 ) and an inner annular gap nozzle ( 5 ) surrounds concentrically, the ring jet nozzle, which can be supplied with liquid medium, having a wall section ( 28 ), which wall section in the direction of the mouth of the adjacent, air-supplied (ventilated) annular gap nozzle, indicates that in the vicinity of the air-gap nozzle, a jet nozzle Adhesive wall ( 9 , 23 ) is formed and the directional orientation d it can be influenced by supplying (ventilation) the air-supplied annular gap nozzle. 4. A jet nozzle according to one of claims 1 or 3, characterized in that in the center ( 8 ) of the inner annular gap nozzle ( 5 ) a jet adhesive wall ( 9 ) is provided, which is preferably designed as a cone, but at least as a circular cone. 5. A jet nozzle according to one of claims 1, 3 or 4, characterized in that downstream of the annular gap nozzles ( 5 , 7 ) an inwardly curved conical ring wall ( 12 ) which is at least designed as a blunt circular cone is provided, which annular wall ( 12 ) is provided with forms a flow channel ( 16 ) on its inside, which has a collecting nozzle ( 13 ) near the annular gap nozzles ( 5 , 7 ) and a central outlet nozzle ( 14 ) downstream,

• 6. jet nozzle in particular according to claim 5, characterized in that the annular wall ( 12 ) is axially displaceable.

7. jet nozzle according to one of claims 5 or 6, characterized in that the annular wall ( 12 ) is surrounded at a distance from an outer casing wall ( 15 ), the outer wall of the annular wall ( 12 ) and the inner wall of the casing wall ( 15 ) form a flow channel ( 16 ). 8. jet nozzle according to claim 7, characterized in that both annular gap nozzles ( 5 , 7 ) open into the flow channel ( 16 ). 9. Single jet nozzle in particular according to one of claims 1 or 3 to 8, characterized in that an air supply line ( 10 ) leads through the axial center of the jet adhesive wall ( 9 ), which air supply line ( 10 ) with an outlet opening ( 11 ) in the front center the beam adhesive wall ( 9 ) opens. 10. A jet nozzle according to one of claims 1 or 3 to 9, characterized in that a circumferential, radially projecting edge ( 31 , Fig. 1a) is formed on the wall formed between the inner annular gap nozzle ( 5 ) and outer annular gap nozzle ( 7 ) which edge ( 31 ) protrudes into the water-carrying channel. 11. A jet nozzle according to one of claims 1 or 3 to 10, characterized in that in the area between the downstream central outlet nozzle ( 11 ) and at least one nozzle segment ( 30 , 30 a, b, c) of the annular gap nozzle ( 5 , 7 ) a supply channel ( 20 ) is formed. 12. Single jet nozzle according to one of claims 1 or 3 to 11, characterized in that the approach to the inner annular gap nozzle ( 31 ) of the frustoconical jet abutment wall ( 9 ) projects beyond the mouth of the outer annular gap nozzle ( 7 ). 13. jet nozzle according to claim 2 or 3, characterized in that the outflow channel ( 22 ) forming walls of the inner annular gap nozzle ( 5 ) have a radially outwardly extending wall section and radially outside of the outer annular gap nozzle ( 7 ) a circular conical, at least conical, the outer annular gap nozzle ( 7 ), jet-adhesive wall ( 23 ) is formed. 14. A jet nozzle according to claim 2 or 3, or 13, characterized in that the outflow channel ( 22 ) forming walls of the inner annular gap nozzle ( 5 ) have a radially outwardly extending wall section and radially outside of the outer annular gap nozzle ( 7 ) a circular conical, at least conical, the outer annular gap nozzle ( 7 ), beam-adhesive wall ( 23 ) is formed. 15. jet nozzle according to one of claims 2 or 3, or 11 to 14, characterized in that radially outside of the outer annular gap nozzle ( 7 ) an annular gap nozzle ( 7 ) comprising substantially conical with incline outwardly extending beam wall ( 23 ) is which jet adhesive wall ( 23 ) with its inner diameter forms a protruding edge ( 32 ), which edge slightly projects above the mouth of the inner outflow channel ( 33 ) and tangentially touches the jet angle a of the inner annular gap nozzle ( 5 ) and in this protrudes slightly. 16. Einstahldüse according to one of claims 2 or 3, or 11 to 15, characterized in that the wall formed between the inner annular gap nozzle ( 5 ) and the outer annular gap nozzle ( 7 ) has a circumferential radially inwardly projecting, jumping into the water-carrying channel edge ( 32 ). 17. A jet nozzle according to one of the preceding claims 1 to 16, characterized in that at least one of the annular gap nozzles has a plurality of webs ( 17 , 18 ) which interrupt the annular gap, which webs the annular gap nozzle into a plurality of nozzle segments ( 30 , 30 a, 30 b, 30 c) divided. 18. A jet nozzle in particular according to claim 17, characterized in that the nozzle segments ( 30 , 30 a, 30 b, 30 c) formed on the annular gap nozzle ( 5 , 7 ) individually via provided outwardly leading air supply channels ( 19 , 19 a , 19 b, 19 c) from a source (Q₁, Q ₂ , Q ₃ ) can be supplied. 19. Single jet nozzle according to one of the preceding claims 1 to 18, characterized in that the directional orientation of a water jet which can be emitted from an annular gap nozzle ( 5 , 7 ) can be changed by ventilating individual nozzle segments ( 30 , 30 a, b, c) of a second annular gap nozzle . 20. jet nozzle in particular according to one of the preceding claims 1 to 19, characterized in that the jet nozzle ( 1 ) can be operated as a multivibrator. 21. A jet nozzle according to one of the preceding claims, 1 to 20, characterized in that the air supply is carried out by a compressed air generating blower which can be operated with electrical energy, which blower can be regulated in terms of power and operated at intervals and at least one annular gap nozzle ( 5 , 7 ) or a nozzle segment an annular gap nozzle can be acted upon by the compressed air generated by the blower. 22. A jet nozzle according to one of claims 1 or 3 to 10, characterized in that when the outer annular gap nozzle ( 7 ) is supplied with water, this can be dispensed from the central outlet nozzle ( 14 ) and that with simultaneous supply to the outer annular gap nozzle ( 7 ) with water and the inner annular gap nozzle ( 5 ) with air can be used to generate a water / air mixture which can be dispensed radially outside the annular wall ( 12 ). 23. A jet nozzle according to one of claims 2 or 3 or 11 to 16, characterized in that when the inner annular gap nozzle ( 5 ) is supplied with water, the water jet can be emitted radially outwards and that with simultaneous supply to the outer annular gap nozzle ( 7 ) with air , a mixture of water and air can be generated and dispensed in a funnel shape. 24. A jet nozzle according to one of the preceding claims, 1 to 23, characterized in that the free cross sections of the supply channels ( 4 , 6 ) are arranged in the region of their outlet openings forming an annular gap nozzle ( 5 , 7 ) at a relative angle of less than 120 °.