DE102004049797A1 - Method and device for noise reduction of jet nozzles - Google Patents

Abstract

Method and device for noise reduction of jet nozzles by subdivisions into individual nozzles or individual nozzle chambers.

Description

Jet nozzles are known from a variety of methods, including from the cold blasting technique such as. the dry ice blasting process. The use of jet nozzles will hinders or prevents by the associated noise, the at a corresponding speed of the carrier gas stream or the carrier liquid stream occurs. Especially in the supersonic speed range volumes from far over reached a hundred decibels, sometimes even over one hundred and thirty decibels. Experiments with attached mufflers have particular in the cold blasting technique so far not or only to a relatively insignificant Reduction of noise emissions guided.

purpose The invention mentioned here is a homogeneous and if necessary also far fanned out jet to produce with reduced noise. Experiments have been surprising shown that the noise emissions with decreasing nozzle cross-section with otherwise constant conditions with a parallelism decrease. Several jets with smaller cross-sectional areas, in the total area a jet with a big one Cross sectional area match, are opposite the jet with big Cross section considerably quieter. However, it has been shown that the noise reduction at a too small distance and the same beam direction of the nozzle jets strongly decreases or is no longer measurable.

The 1 shows a modified embodiment of the jet device, their individual nozzles 1a preferably from an upstream nozzle prechamber 1b depart and as a whole a round total area 1c exhibit. The individual nozzles are mounted at a distance from each other, which ensures that the individual jets remain cleanly separated.

The 2 shows another modified form of the jet device, their individual nozzles 2a as a whole a rectangular total area 2 B exhibit. In order to produce a continuous jet pattern while maintaining the necessary for noise reduction distance of the nozzle jets to each other, the individual nozzles are preferably mounted offset.

The individual nozzles can be formed with divergent beam direction, the Beam directions can doing so from the inside out fanned or from the outside inside on a surface to be focused. The individual nozzles can be in all described embodiments also as a nozzle chambers within a massive total nozzle be educated.

The 3 shows a further embodiment of the jet device, on the output side, a sheath 3c is attached, which is preferably designed as a Venturi nozzle.

Of the here through the jets sucked air flow leads to a temperature of the jet nozzles and contributes by the formation of a Sliding layer between jet and atmosphere also continue to reduce noise at. Alternatively, each individual nozzle can be provided with a jacket be, preferably as a Venturi nozzle is trained.

at Cold jets As with the dry ice blasting technique, it can be especially in tight Nozzle cross-sections come to the fact that the residual air moisture in the used as a carrier gas Compressed air or another carrier gas precipitated as water ice and icing and then constipation Lead jet device or the jet nozzle. Here it may be appropriate be to heat the jet device or the jet nozzle to this icing or to prevent constipation. The heating can be electric or by means of a warm or hot Medium or a suitably designed burner.

Claims (9)

Blasting method and apparatus for noise reduction of jet nozzles, characterized in that the jet nozzle 1 from several separate individual nozzles 1a each with the cross-sectional area at the narrowest point of each individual nozzle being less than 20 square millimeters each Blasting method and apparatus according to claim 1, characterized in that the individual nozzles 1a are designed as convergent-divergent nozzles, preferably as Laval nozzles Beam method and apparatus according to claim 1 and 2, characterized in that the beam direction of the individual nozzles 1a is different from each other Blasting method and apparatus according to claims 1-3, characterized in that the individual nozzles 3b are different in cross-sectional areas and lengths Blasting method and apparatus according to claims 1-4, characterized in that the respective individual nozzles 1a are mounted at a distance from each other and that the respective distance 1d on the output side, at least 10% of the diameter of the respective individual jet at the outlet opening of the nozzle is present between the individual jet streams. Blasting method and apparatus according to claims 1-5, characterized in that the individual nozzles 3b on the outside by one of the geometry of the nozzle total area adapted, open at the ends sleeve 3c is included, by means of which air is sucked through the jet, which sets as a sheath current sound-insulating around the jet. The sleeve is preferably designed as a Venturi nozzle. The narrowest distance of the sleeve 3c to the individual nozzles 3b is at least 20% of the output side inner diameter of the individual outer individual nozzles. Blasting device according to claim 1-6, characterized in that the total area of the individual nozzles 1a an at least approximately round cross-section 1c having Blasting device according to claim 1-6, characterized in that the total area of the individual nozzles 2a an at least approximately square or rechteckeckigen cross-section 2 B having, wherein the individual nozzles 2a offset from each other are arranged to achieve a continuous jet pattern. A blasting apparatus and method according to claims 1-8, characterized in that the jet devices, preferably the jet nozzles during the Blasting process to be heated so far that a possibly existing moisture of the carrier stream not by ice formation in the jet device and in particular in the jet nozzle do not precipitate and thus disturb or prevent operation