EP2675533A2

EP2675533A2 - Reduced-noise extinguishing nozzles

Info

Publication number: EP2675533A2
Application number: EP12712996.3A
Authority: EP
Inventors: Francois BRYON; Miguel Angel COLL; Michael HÖGE; Erhard Magori
Original assignee: Siemens AG
Current assignee: Siemens Schweiz AG
Priority date: 2011-04-08
Filing date: 2012-03-19
Publication date: 2013-12-25
Also published as: DE102011007054A1; WO2012136468A3; WO2012136468A2

Abstract

A device for discharging an extinguishing medium (13) comprising at least one discharge opening (22) is provided. The discharge opening (22) is distinguished by the fact that the extinguishing medium (13) emerges as a jet of such a flat form that there cannot form within it any flow turbulence that would emit sound waves of a wavelength in the audible acoustic spectrum. This is ensured by the geometry of the discharge opening (22).

Description

description

Sound-reduced extinguishing nozzles

The invention relates to a device for outflow of an extinguishing medium.

In the field of extinguishing nozzles for building-installed Löschanla ^¬ gene various imple mentation forms are known. Generally, pipes are placed at the exit point of the extinguishing system. Conveniently, building-extinguishing systems are ceiling mounted and depending on the volume and geometry more from ^¬ takes place are provided. The pipe ends are then closed with a quenching nozzle. The extinguishing nozzles are usually made as Einschraubteile, so that the assembly ver ^¬ simplifies possible. A typical example of an erase ^¬ nozzle is about a cap nut as an end cap, ge in the holes are drilled ^¬ which form the outlet openings for the extinguishing medium.

The number and the hole diameter can be adapted to the respective extinguishing application and the room size. Ins ^¬ special calculates the number holes for individually. Manufacturer-specific calculation rules or programs are used to calculate the number holes that comply depending on the country, additional regulatory requirements and Che ^¬ levies.

The extinguishing nozzle design also depends on the type of extinguishing medium, whether it is a gas or a liquid.

The nozzle shape can be supplemented for example by Strahlformengeomet ^¬ rien, such as baffles. Furthermore, z. B. for a quenching gas and a throttle device may be provided in the extinguishing nozzle. All previous extinguishing nozzles have the problem that it comes in a deletion process to a large noise. Since a noise level of up to 140 dB can be achieved with different nozzles, this noise level is within a range that can damage the human ear. And even devices in a room to be deleted are at risk. Even with ^{rechtzeiti ¬} ger evacuation of all persons from a room to be deleted, the high noise level is a problem for the stability of about the hard drives in computing or data centers. It has been shown that hard drives already from a noise ^¬ level of 120 dB partially even work incorrectly from 110 dB. At a higher noise level, permanent damage or even destruction can occur.

In order to reduce the noise level in an extinguishing process, in the prior art, the extinguishing nozzles downstream of silencer, which are additionally flowed through. For example, sintered bodies are also used for this purpose. The flow through another component, however, greatly reduces the flow velocity. In addition, certain sound-damping devices are not suitable for chemical extinguishing media, since their evaporation is then not guaranteed. Also, ge ^¬ ensures sufficient mixing of the room air with the extinguishing gas when the flow rate is too strong deposed ago ^¬.

It is an object of the present invention to provide a device for outflow of an extinguishing medium with reduced noise ^¬ winding during operation.

The object is achieved by a device according to claim 1. Advantageous embodiments of the device are the subject of the dependent claims.

The device according to the invention serves for the outflow of an extinguishing medium. In this case, the device has at least one outflow opening, wherein the outflow opening has a geometry, so that a outflow through this outflow opening the medium assumes a beam shape which is at least one extension perpendicular to the direction of propagation less than the lower limit of the wavelength of the audible by the human Ge ^¬ audible acoustic spectrum. This has the advantage that the device can be used to extinguish building spaces in which sensitive technical equipment is operated which would be disturbed or damaged by an ordinary extinguishing system. In addition, the device has the advantage that by the reduced noise level during operation, even persons who are still in a room to be deleted, are not endangered by the noise level.

In an advantageous embodiment of the invention, the outflow opening has a geometry which, in at least one extent, is less than the lower limit of the wavelength of the acoustic spectrum perceivable by the human ear. With such a geometry and maximum dimensions for the outflow opening ensures that the beam shape of the outflowing medium meets the acoustic conditions.

The extinguisher nozzle is so designed in particular, that the cross section of the extinguishing agent jet is very narrow at least in one Rich ^¬ processing, that is, that a very flat jet of the extinguishing medium is flowed out, and can not form flow eddies characterized in the free jet which ^¬ at AKUS table frequencies could radiate sound waves.

In a further advantageous embodiment of the invention the outflow opening to a gap or slot-shaped Ge ^¬ ometrie. That is to say, the outflow opening is much larger or longer in a first expansion than in a second expansion perpendicular to this first expansion.

In particular, therefore, the cross section of the extinguishing agent jet is very narrow in one direction, but very elongated in another direction. Such a flat beam shape can be particularly well through the described slit or slot-shaped Geometry of the discharge opening can be generated. In contrast to previous nozzle shapes that omit approximately rotationally symmetrical gas flows, such as are caused by drilling, the flat gas or liquid jet has the advantage that there is no flow vortex radiated by the human ear detectable acoustic frequencies.

In a further advantageous embodiment of the invention, the outflow opening runs along a straight line. Such long slit or slot-shaped straight geometries for the outflow openings are preferably placed along a pipe ^¬ , which serves equally for supplying the extinguishing medium and to the outflow. Ie, z. B. a pipe section itself represents the extinguishing nozzle.

In a further advantageous embodiment of the invention, the outflow opening extends alternatively on a sheet, in particular a circular arc. This alternative to the straight course is advantageous for example at a pipe end. As at ^¬ describes the outflow opening a circular arc through which the extinguishing medium can escape. In the radial direction, the outflow opening is in turn at most so great that the acoustic conditions are met.

In an advantageous embodiment of the invention, the device has a plurality of outflow openings. The straight slot-shaped outflow openings can in particular parallel to each other z. B. be arranged in the pipe jacket. The Kreisbogenausströmöffnungen can z. B. be mounted as a concentric circular openings of different diameters at a pipe end.

In a further advantageous embodiment of the invention, the outflow opening has a through opening.

That is, the outflow is a continuous, not interrupted ^¬ opening in the erase nozzle, z. For example, a long column. An alternative to this is a further advantageous embodiment. Design of the invention, in which the outflow has a plurality of small juxtaposed openings. That is, the outflow opening is composed of a plurality of small holes. These can be in particular boreholes.

These small openings, which form the outflow opening, are preferably lined up in such a way that they act on an outflowing medium essentially like a through-opening. The plurality of small openings has the advantage of mechanical stability of the device and a simple manufacturing variant in which the openings can be re ^¬ alisiert as boreholes.

In a further advantageous embodiment of the invention, these small openings which form the outflow opening are arranged along a straight line. Alternatively, the openings of the outflow opening can be arranged along an arc, in particular a circular arc. These two forms of execution are particularly suitable for a pipe or a cone ^¬ nozzle. The straight openings along the Rohrach se can extend in the pipe jacket. The arcuate outflow openings are preferably arranged at a pipe end in the final ^¬ part.

With the use of suitable nozzle shapes can be reduced by the geometry of the sound production. In a flat jet, it is spatially impossible for eddies with acoustic rotational frequency to form in the outflowing volume. In addition to the reduction in noise during operation, the device also has the advantage that the specified discharge nozzles are easy to manufacture. The new shape allows for the length of the opening to a good evaporation of chemical extinguishing agents. Chemical extinguishing agents are for example Halon, HFC 227 or Novec. Also, a high flow of Löschme ^¬ dium is ensured and a rapid homogeneous distribution of the extinguishing medium in the room. The distribution of the extinguishing medium achieved by the extinguishing nozzles ensures rapid a minimum extinguishing agent concentration in all parts of the room. Depending on the design of the extinguishing nozzle, a single nozzle for ei NEN space may be sufficient due to the new shape of the outflow openings, which reduces the installation cost The design is scalable, ie even on rooms unterschiedli rather resizable, only by adjusting individual geometrical parameters, without the To change the basic design. In addition, the extinguishing nozzles described are very inexpensive to produce.

Embodiments of the present invention will be described by way of example with reference to FIGS. 1 to 12 of the drawings. It shows

1 is a screw-in extinguishing nozzle of the prior Tech technology,

FIG. 2 shows a first embodiment of an outflow opening along a pipe, FIG.

3 shows a cross section of this first embodiment,

4 shows a longitudinal section of this first embodiment,

5 shows a second embodiment of a plurality of outflow openings along a tube,

6 shows a third embodiment of a plurality of outflow openings along a tube,

7 shows a cross section of this third embodiment,

8 shows a longitudinal section of this third embodiment, FIG. 9 shows a further embodiment of a plurality of outflow openings, FIG.

10 is a cone nozzle with a further imple mentation egg ner outflow, 11 is a plan view of this further imple mentation ei ^¬ ner outflow,

12 is a longitudinal section through the cone nozzle,

13 a cone nozzle with a plurality of outflow openings,

14 is a plan view of the outflow openings of the cone ^¬ nozzle and

15 shows a longitudinal section through the cone nozzle with the several ^¬ ren outflow.

FIG. 1 shows an extinguishing nozzle, as known from the prior art. In this case, a pipe 11 protrudes from the ceiling of a room to be deleted. The tube 11 is the supply line for the extinguishing medium 13. This tube 11 is closed with the extinguishing nozzle 14. Perspectively shown is an end cap in the form of a cap nut 15 which is screwed onto the tube 11. The end cap 15 has outflow openings 12 formed by bores in the end cap 15. From these outflow openings 12, the extinguishing medium 13 flows out in a conical jet, so that as far as possible a large radius can be covered.

FIG. 2 shows a tube 21 in a side view. This tube 21 serves both the supply of the extinguishing agent 13 and the outflow of the extinguishing agent, i. So as extinguishing nozzle. For this purpose, the tube 21 has an outflow opening 22. This runs as a narrow slot along the tube axis. Marks III and IV are also shown in FIG. 2, which mark the cross section III through the tube 21 shown in FIG. 3 and the longitudinal section IV through the tube 21 shown in FIG.

Figure 3 thus shows the cross section III 21 through the pipe ^¬ Since at the very narrow outflow opening 22 can be seen. In particular, it is shown that the expansion of the discharge opening voltage 22 along the tube panel circumference is very low, is in particular ^¬ sondere less than 17 mm.

Figure 4 shows the longitudinal section IV through the tube 21. In this case, the sectional plane IV is chosen so that the outflow ^¬ opening 22 is shown at one of the edges. At a first end of the tube 21 this is completed, at the other end of the tube 21, a passage 23 is shown, which serves as Me ^¬ serving feed pipe 23 to the 21st

Figure 5 shows a further disclosed embodiment, the tube 21 as the extinguishing nozzle, said plurality of voltages having Ausströmöff ^¬ 22 which are arranged in parallel. Thus, as before, each of the discharge ports 22 but tra gene ^¬ a plurality of openings 22 fulfills the conditions to the Ausströmgeometrie of the beam to a higher throughput of extinguishing medium at 13.

FIG. 6 shows a further alternative embodiment of the outflow opening 22. In this case, again a tube 21 is used as extinguishing nozzle. The figure 6 again has the characteristic ^¬ drawing of transverse and longitudinal section VII, VIII, which are shown in Figures 7 and 8. In this case, this Ausfüh ^¬ tion form no continuous slot as outflow 22, but there are a plurality of small openings 20 are shown, which are arranged side by side, that they cause a very similar beam shape of the outflowing medium 13, such as a continuous elongated slot. That is, the diameter of the openings 20, which are in particular boreholes, meets the highest level of noise protection. The close to each other ^¬ succession along the tube axis causes suffi ^¬ accordingly extinguishing medium can flow 13 and that, combine the beams which are masked by the small openings 20 suitable.

FIG. 7 once again shows the cross section through the plane VII of the tube 21. 22 cut. The diameter of a drill rod 22 is in particular a maximum of 17 mm.

FIG. 8 again shows the longitudinal section through the tube 21 along the plane VIII. In this case, the outflow openings 22 can be seen on the longitudinal side of the tube 21. The tube 21 is again closed at a first end and has an opening for supplying media 23 at the second end. FIG. 9 shows an alternative embodiment of the extinguishing nozzle. In this case, the tube 21 is arranged perpendicular to a connecting piece 26. This connector 26 has at its obe ^¬ ren end the opening 23 for the media supply of the extinguishing medium. This is in particular made as a screw, which can be mounted on a pipe end, which projects, for example, from the ceiling. At the lower end of the connector 26, the pipe 21 is arranged perpendicular thereto, which can be supplied via the feed 23 serving Me ^¬ with extinguishing medium. 13 At both ends of the tee, the tube 21 is closed. It has the outflow openings 22 along the tubular jacket. In particular, in the example shown in FIG. 9, a multiplicity of outflow openings 22 are shown. These do not have a continuous opening, but in turn have a plurality of small openings 20 arranged side by side so that jets emerging through these small openings 20 combine to form a single flat jet of extinguishing medium 13, which forms the acoustic conditions. In the example shown, the pipe is not a conical pipe jacket, but a geometry with an octagonal cross-section. The height h of the tee is in particular 65 mm. The length 1 of the T-piece, which corresponds to the length of the tube 21, is in particular 128 mm. The media supply port 23 has in particular ^¬ sondere to a diameter of 19.05 mm. The small openings 20 are in particular boreholes. The diameters of the small openings 20 are in particular 25.4 mm. Preferably, the diameters of these openings 20 are less than 25.4 mm. The distance between the openings 20 along an outflow opening 22 is in particular 2.53 "or less.

FIGS. 10 to 15 show an alternative embodiment of an extinguishing nozzle in the form of a cone nozzle 24. This is initially shown in FIG. 10 in a side view. The cone ^¬ nozzle 24 initially consists of a pipe section 21, which extends in ^¬ particular cylindrical. Because of the cone-shaped terminal 25 of the ^¬ Konusdüse 24 includes with the direction of Löschdüsenvor-. In this final cone 25 is the

Outflow opening 22. This is shown in the figure 10 as a continuous slot. FIG. 10 has an identification of a sectional area XII which is shown in FIG. Furthermore, in FIG. 10, which is indicated

Top view XI is shown on the cone nozzle 24 in Figure 11. 11 shows a plan view XI on the kegelför ^¬ migen conclusion 25 of the cone nozzle 24. There, it can be seen that the continuous outflow opening 22 describes a complete circular arc. Through such a shaped outflow opening 22, the extinguishing medium 13 will emerge from the nozzle in the form of a conical jet. However, the cone beam is not fully filled as in a hole, but the Löschmedi ^¬ 13 radiates only as a shallow cone coat. This ensures the noise level reduction.

FIG. 12 shows a longitudinal section through the cone nozzle 24 shown in FIG. 10 along the surface XII. It can be seen on the one hand, the media supply 23 in the conical nozzle 24, which may be connected in particular to a supply pipe. On the opposite side of the conical nozzle 24, on the conical end 25, there are the outflow openings 22, through which the extinguishing medium 13 can leave the conical nozzle 24. Within the conical nozzle 24, the supply line 23 is branched so that it reaches the outflow openings 22.

Figure 13 shows an alternative embodiment of the flow orifice from ^¬ 22 for a Konusdüse 24. The flow orifice from ^¬ 22 again not designed consistently, special It has a plurality of small openings 20, which together form an outflow opening 22. This outflow opening 22 is again arranged on a circular arc at the conical end 25 of the cone nozzle 24. In FIG. 13, the longitudinal section XV is identified by the cone nozzle 24, as shown in FIG. FIG. 14 shows a plan view of the cone nozzle 24 from the side XIV, which represents the conical end 25.

In FIG. 15, the opening 23 for the media supply is shown again on one side and the outflow openings 20 on the opposite side of the nozzle 24.

Claims

claims

1. A device for outflow of extinguishing medium (13) with at least one outflow opening (22), wherein the Ausströmöff ^¬ voltage (22) has a geometry so that through this outflow opening (22) outflowing medium (13) assumes a beam shape, which in at least one extension perpendicular to the direction of propagation is less than the lower limit of the wavelength of the acoustic spectrum perceivable by the human ear.

2. Device according to claim 1, wherein the outflow opening (22) has a geometry which is less than the lower limit of the wavelength of the perceptible by the human auditory acoustic spectrum in at least one expan ^¬ tion.

3. Apparatus according to claim 1 or 2, wherein the outflow opening (22) has a slit or slot-shaped geometry.

4. Device according to one of the preceding claims, wherein the outflow opening (22) extends along a straight line.

5. Device according to one of the preceding claims 1 to 3, wherein the outflow opening (22) along an arc, in particular ^¬ special runs a circular arc.

6. Device according to one of the preceding claims with a plurality of outflow openings (22).

7. Device according to one of the preceding claims, wherein the outflow opening (22) has a through opening.

8. Device according to one of the preceding claims 1 to 6, wherein the outflow opening (22) has a plurality of openings (20).

9. Apparatus according to claim 8, wherein the openings (20) of the outflow opening (22) are lined up so that they are in Act essentially as a through hole on a ausströ ^¬ Mendes medium (13).

10. Apparatus according to claim 8 or 9, wherein the openings (20) of the outflow opening (22) are arranged along a straight line.

11. The device according to claim 8 or 9, wherein the openings (20) of the outflow opening (22) along an arc, in particular a circular arc are arranged.