RU61353U1 - SOUND ABSORBING CONSTRUCTION WITH PERFORATED FILLER IN THE FORM OF FOLDED STRUCTURE - Google Patents

Abstract

The utility model relates to the field of noise absorption in the air intakes of gas turbine units or jet propulsion systems.

The essence of the utility model lies in the fact that the sound-absorbing structure, consisting of two metal sheets and a filler located between them in the form of a folded structure. The first metal sheet is perforated, and the filler is made in the form of a perforated corrugated sheet, which is a series of zigzags with alternating depressions and peaks.

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Description

The utility model relates to the field of noise absorption in the air intakes of gas turbine units or jet propulsion systems.

Currently, honeycomb panels are used as sound absorbing structures. Cellular sound-absorbing structures are three-layer structures consisting of two metal sheets and a honeycomb placed between them (Copyright Certificate No. 610956, IPC E 04 B 1/74, published June 15, 1978, Bulletin No. 22). From the point of view of acoustics, the use of honeycomb structures provides greater sound absorption efficiency in a limited frequency range, which depend on the height of the honeycomb core.

The disadvantage of such designs is that they have a relatively narrow range of effective sound absorption, therefore, to reduce noise having a broadband nature, their use is inefficient.

A known structure based on a filler in the form of a folded structure, selected as a prototype. The heat and sound insulating multilayer panel consists of several layers, each of which contains metal sheets and a filler located between them, which is made in the form of a corrugated sheet, which is a series of zigzags with alternating depressions and peaks. (Patent No. 52877, IPC E 04 B 1/88, published April 27, 2006, Bulletin No. 12). In terms of acoustics, the use of pleated aggregate in sound absorbing

designs provides a significantly larger frequency range of sound absorption than in the case of the use of honeycomb.

The disadvantage of the prototype is that, compared with a sound-absorbing structure based on a honeycomb core, a structure based on a filler in the form of a folded structure has lower sound absorption efficiency at the tuning frequency of the structure.

The utility model is based on the task of increasing the sound absorption efficiency of a filler-based structure in the form of a folded structure at the frequency of the structure tuning.

The problem is solved due to the fact that the sound-absorbing structure, consisting of two metal sheets and a filler located between them, in the form of a folded structure, is characterized in that the first metal sheet is perforated and the filler is made in the form of a perforated corrugated sheet, which is a series of zigzags with alternating valleys and peaks.

This sound-absorbing structure is illustrated in the drawing, which shows a sound-absorbing structure including a metal perforated sheet 1, a perforated filler in the form of a spatially folded structure 2, non-perforated metal sheet 3.

The drawing clearly shows that due to the perforation of the folded filler, not only air volume A, but also cavity B, starts to work on sound absorption. This significantly increases the sound absorption efficiency at the design tuning frequency with the geometric characteristics remaining unchanged. The proposed design retains almost all the advantages of a honeycomb core (light weight, strength, rigidity, etc.), but dramatically reduces the cost of sound-absorbing

design, especially metal, due to a simpler manufacturing technology. When using a spatially folded filler instead of honeycombs, the range of effective sound absorption is expanded, since, in contrast to the honeycomb case, there are no resonators with a fixed cavity height, and the resonator height variability (both in the transverse and in the longitudinal direction) should smooth out the sharp peak of noise attenuation at the resonant frequency .

One of the most important advantages of a filler in the form of a spatially folded structure is the high flexibility of sound absorption characteristics by changing the geometric parameters of the structure based on this filler, which are much easier, cheaper and faster to change in view of simple and cheap equipment. The second advantage is a wide selection of materials used.

The design has the same characteristics and resistance to weathering, which ensures a high resource of the structure. It is resistant to dirt, moisture, soot, etc. The spatially pleated aggregate structure has natural channels that allow condensate to be removed. The use of metallic materials allows the use of panels in a wide range of temperatures and highly aggressive environments. This property is important for the use of panels in the exhaust devices of gas turbine plants.

The inventive sound-absorbing design has the following characteristics:

- Resource - at least 30 years

- Range of effective sound absorption - 100 ... 10000 Hz

- The cost of aggregate is 5 times cheaper than cellular structures.

Claims (1)

A sound-absorbing structure consisting of two metal sheets and a filler located between them in the form of a folded structure, characterized in that the first metal sheet is perforated, and the filler is made in the form of a perforated corrugated sheet, which is a series of zigzags with alternating hollows and peaks.