FI108406B - Jet nozzle for developing double jet cone - Google Patents

Abstract

The radial spray nozzle is built into a pipe conduit of the fire-fighting unit comprises a housing in which is formed a torsion mixt. chamber constituting a flow body. The flow body (3) is located in a flow housing (6) supported by a cover housing (11), which at the lower end has a cylindrical tube (12) with a cylindrical nozzle aperture (10). The flow housing in common with the cover housing forms an outer torsion mixt. chamber (13) and an annular gap (14) at a distance from the lower end of the tube (12). The cover housing is provided with one or more tangential and radially inclined holes (15) which end in the outer torsion mixt. chamber.

Description

108406

This invention relates to a spray nozzle for the development of spray mists by means of a low pressure method, in particular to a fire, by means of a fixed water mist fire extinguishing means, wherein forming a flow body having an outer surface provided with one or more helical grooves having an axial inlet, wherein the vortex grooves together with the housing form vortex channels terminating in the vortex mixing chamber formed by the housing and the flow member 15 and terminating in a

Such nozzles are used for spraying liquids, whereby a uniform jet pattern is sought with respect to the liquid distribution, especially for fire extinguishing devices. DD 116 398 discloses such a nozzle formed by a nozzle cavity piece and a nozzle insert having an outer vortex groove. These nozzles 25 mainly spray the circular ring. The area inside the circular ring is sprayed only slightly. This means that when the water flow is released from the nozzle, a cavity cone is formed because of the formation of internal vortexes in the jet cone. Another drawback associated with the older shower nozzle 30 is that the vortex channels formed tend to clog and the vortex body also requires long machining times during manufacture.

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In another 35 nozzles according to DD 211 805, two fluid streams are mixed at the outlet. The disadvantage of this solution is the strong pressure dependence of the partial flow sections. Only single currents work without intermingling.

It is an object of the present invention to provide a jet nozzle which avoids the disadvantages associated with older jet nozzles and which develops a jet cone, which is a full cone with more intense turbulence.

This object is solved by arranging the flow body in a flow housing supported by a jacket housing having at its lower end a cylindrical tube having a cylindrical nozzle opening, the flow housing together with the jacket housing forming an outer vortex mixing chamber and provided with one or more tangentially and radially inclined bores terminating in an outer rotor resection chamber.

This jet nozzle is used to develop an internal jet cone 20 with large water droplets and an external jet cone with small water droplets. The water stream flowing through the inner vortex chamber exits the nozzle opening for a short distance in a centralized, turbulent, higher-pressure inner jet.

, .25 The cylindrical tube '* associated with the flow member and the casing housing, which form the annular gap, stabilize and concentrate the outside jet outflow from the ring nozzle. After this distance, an outer jet cone is formed, where a vortex zone is formed inside the jet shell 30. Outer nozzle nozzle nozzle. the special structure of the outlet produces a fine spray mist. The external jet cone thus formed is very stable from the operating pressure, even if the pre-pressure, i. pressure in the pipeline gear-35 lee.

: · The flow angles of the outflow spray mist can be ♦ 108406 3 with the help of appropriate flow piece and nozzle geometry between 60 ° -140 ° for the external spray cone and 60 ° -90 ° for the inner spray cone. Details are given in the description of the drawing.

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The outer, higher annular gap and the inner cylindrical orifice provide intense mixing of the two jets with a full cone.

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The nozzle outlets of the two nozzles are aligned with each other such that the outer jet cone at an angle passes through the inner jet of the jet and thereby accelerates the inner jet cone. The flow rates for the two water streams are matched to each other so that they are equal. As a result, the two drops of larvae are partially mixed together. This has the consequence that the exterior fine jet cone avoids the typical cavity cone 20 at the vortex nozzles at the outflow of water from the nozzle. Due to the intermingling of the tear flocks of the jet cones, the total jets have a greater range and better permeability. Clipping and deepening effect are improved. The nozzle is therefore particularly well suited for fire fighting, (<25 for particularly intense fires during the fire cooling phase).

The spray nozzle according to the invention for developing a double jet mist cone by means of a jet jet has the following other advantages: {* * - the partial jet cone avoids the formation of a hollow cavity due to the partial mixing with the fine outer jet cone.

35 - The shower released by the internal nozzle orifice acts as a bracket. . as a medium for fine droplets in the outer spray 4 108406.

By mixing the two jets of cone 1, a flock of drops is formed, consisting of coarse droplets and 5 fine droplets, which are particularly suitable for fire fighting in the case of intensely burning fires.

The drawing shows a structural pre-10 character of the invention and will be explained in more detail below. Further, an embodiment of the invention will be described, with reference to other features of the invention, in which: Figure 1 is a sectional view of a spray nozzle;

Fig. 2 is a section along line A-B in Fig. 1, and Fig. 3 is a section along line C-D in Fig. 1.

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The jet nozzle 1, which is mounted radially in the conduit 2, comprises an internal flow housing 6 and a surrounding casing 11. the inner bore 24 of the flow cavity 6. The outer surface of the cone-shaped central portion 16 is provided with a plurality of helical vortex grooves 4 connected by 30 axial supports in the cylindrical portion 23; with traps 5. The flow cavity 6 is formed by a conical bore 17 at the central portion 16, and the two portions 6, 17 are structured such that they fit together in a nearly clearance-free manner. By this construction, vortex passages 7 are formed which terminate in an inner vortex mixing chamber 8. 108406 5 through a venting bore 19 engages with a cylindrical nozzle opening 10. The pin 9 terminates in connection with the bore 19. The jacket housing l1 surrounding the flow housing 6 is constructed to form an outer vortex resection chamber 13 which, through a tapered member, engages the annular slot 14. The annular slot 14 is located adjacent the cylindrical tube 12 of the flow housing 6 and is positioned above the lower end of the tube 12. The jacket housing 11 is further provided with a plurality of radially and tan-10-inclined bores 15 which terminate in an outer vortex mixing chamber 13. For better water supply, the jacket housing 11 is surrounded by a housing 20 which together with the jacket housing 11 forms an annular strand 21. The housing 20 15 together with the annular space 21 is also an advantageous construction for manufacturing reasons. Further, the lower end 22 of the housing 20 is extended so far down that it protects the cylindrical tube 12 of the flow housing 6.

20 The water to be injected is guided along two separate waterways. The other route leads through the inlet openings 5 and the vortex passages 7 to the cylindrical nozzle opening 10 and forms an internal jet cone. The second water path, through the annular space 21 and the bores 15, leads to an annular cavity 14 located up to about .25 degrees from where the water exits as an external jet.

The incoming flow is stabilized and accelerated by the vortex channels 7 and the inner vortex mixing chamber 8. The flowing ve-30 side exits the cylindrical nozzle opening 10:; centered, turbulent and pressurized interior spray f '· * * with larger water droplets. The vortex channels 7 run helically at an angle of 30 ° to 60 °. This design further accelerates the flow of water in the vortex ducts compared to previously known spray nozzles. The vortex channels also tear open the droplets, breaking the surface of the droplets. This increases the range and permeability of the full 6 108406 cone-shaped mist jet at the fire site. The vortex channels 7 end up in the inner vortex recirculation chamber 8, which causes the water flow into a vortex motion and thereby creates an additional surface rake 5. The water flow is stabilized and concentrated in the inner vortex chamber 8 by a pin 9 before it exits the jet nozzle through the nozzle opening 10. The inner jet cone so developed is known for a slightly wider droplet spectrum. The inner jet cone droplets serve as a carrier medium for finer droplets in the outer jet cone.

The annular gap 14 formed by the cylindrical tube 12 and the jacket housing 11 further stabilizes and centers the outer jet cone exiting the annular jet 14 in the outer vortex mixing chamber 13. An interior swirl belt is provided inside the outer jet cone which provides a particularly good swirl zone.

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In order to produce a uniform, stable and spray mist of finely divided, coarse water droplets, the ratio between the cross-section of the vortex channels 7 and the largest ring cross-section # 25 of the inner rotary mixing chamber 8 is 1: 2 to 1: 5 also according to the invention between 1: 2 and 1:10. The inner jet cone is released as a full cone without any instability due to the special construction of the inner vortex mixing chamber, where-; sa is the cylindrical pin 9 of the flow piece 3 and the cylindrical nozzle opening 10 located below it. '

For the sake of simplicity of operation, larger tangential bores 15 may be used at the flow inlet (bores 15) leading to the outer ring 35 to the slot 14, thereby substantially reducing the clogging tendency of the outer ring slot nozzle.

In order to further spray the water, the fluid film has more open opening. This can be accomplished such that the water guiding surfaces in the outer 13 and inner vortex mixing chamber 8 and the inner surface of the flow member 3 in connection with the vortex channels 7 are roughened. Roughing can be carried out in a conventional manner.

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Claims (10)

A jet nozzle (1) for producing jets by means of a low pressure method, in particular for fire protection by means of fixed water mist fire extinguishing devices, wherein the jet nozzles (1) integrated radially in the fire extingu (3) having an outer surface 10 provided with one or more helical vortex grooves (4) having an axial inlet (5), wherein the vortex grooves (4) together with the housing (6) form vortex channels (7) terminating in the housing (6) and in the vortex mixing chamber (8) formed by the flow member (3), and that the tapered portion (9) of the flow member terminates in front of the cylindrical nozzle opening (10), characterized in that the flow member (3) ) provided at its lower end with a cylindrical tube 20 (12), having a cylindrical nozzle opening (10), wherein the flow housing (6) together with the jacket housing (11) forms an outer vortex mixing chamber (13) and an annular slot (14) at a distance from the lower end of the tube (12), and the jacket housing is provided and a radially inclined bore (15) terminating in an outer vortex mixing chamber (13). A shower nozzle according to claim 1, characterized in that the flow body (3) and the flow chamber (6) are removably arranged in the shell housing (11). Jet nozzle according to claims 1 and 2, characterized in that the cone-shaped central part (15) of the flow body (3) is fitted in a conical bore (17) in the flow cavity (6) almost free of clearance, the conical bore (17) less than half the length of the cone-shaped central portion (16) <108406 and coincides with the cylindrical bore (18) forming the inner vortex mixing chamber (8). Jet nozzle according to claims 1-3, characterized in that the inner vortex mixing chamber (8) has a tapered bore (19) with which the pipe (12) of the flow piece (3) is located, and a bore (19) having a smaller diameter. engages with a cylindrical nozzle opening (10). 10 Spray nozzle according to claims 1-4, characterized in that the housing (11) is surrounded by a protective housing (20) connected to the pipeline (2), the outer diameter of the housing and the inner diameter 15 of the housing forming an upwardly open annular space (21) and radially inclined bores (15) leaving. A shower nozzle according to claims 1-5, characterized in that the lower end (22) of the protective housing (20) extends in front of the cylindrical tube (12) of the flow housing (6). Jet nozzle according to claims 1-6, characterized in that the upper part of the flow body (3) consists of a cylindrical part (23) receiving the inlets (5), which is arranged in the cylindrical bore (24) of the flow body (6). Jet nozzle according to claims 1-7, characterized in that the bores (15) are inclined tangentially by an angle α between 15 * -45 *, preferably between 30 * -40 *, and radially by an angle β between 5 * -40 *, preferably 35 between 10 * -20 *. Jet nozzle according to claims 1-8, characterized in that the ratio between the cross-section of the vortex channels (7) and the largest annular section of the inner vortex mixing chamber (8) lies between 1: 2 and 1: 5 and that the bores (15) and the ratio of the largest annular cross-section of the outer wheel-5 resection chamber (13) is between 1: 2 and 1:10. Jet feeder according to claims 1-9, characterized in that the outer (13) and inner vortex mixing chamber (10) have water-guiding surfaces and the inner surface of the flow body (3) in connection with the vortex channels (7). 15