BG558Y1 - Aerodynamic silencer - Google Patents

Abstract

The silencer is built into air ducts of ventilation and air conditioning installations for performing artificial sound silencing. It has a simplified and safe in operation design and longer operational life. It consists of a supporting housing (1) the internal surfaces (5, 6) of which have a layer of extruded polyethylene (3). In the housing (1) noise-absorption elements (2) are fitted having a flow around shape fitted in at least two parallel rows (4). Elements (2) along their entire lengths are executed of homogenous material and are covered by a noise-absorbing layer (3) made of extruded polyethylene, the thickness of which is at least 5 times bigger than the thickness of the noise-absorption elements (2). 5 claims, 3 figures

Description

The utility model refers to an aerodynamic silencer built into the ducts of ventilation and air-conditioning systems intended for artificial silencer.

BACKGROUND OF THE INVENTION

A silencer known to reduce the level of aerodynamic noise in ventilation systems, consisting of an active part, constituting a protective casing (housing), to which a sound absorbing material is limited, limited by a perforated screen. Sound absorbing bodies, representing triangular cross-section prisms filled with sound absorbing material / 1 /, are attached to one another.

Also known is a silencer for air flow from a ventilation system, which consists of a housing with noise-absorbing plates (elements) placed therein in parallel. Each plate contains three parts. The first part is arranged in the direction of flow and is made of fibrous material. It absorbs high-frequency noise, the second part is filled with a porous body and absorbs mid-frequency noise, and the third part is formed by bulk granular matter absorbing the low-frequency noise / 2 /.

Another silencer is known, consisting of a housing with an inlet and outlet pipe, in which are located noise absorbing elements, designed as damping plates, perpendicular to the axis of the housing at a distance from each other. The damping plates are secured to the two opposite inner surfaces of the housing so that a labyrinth channel is formed. In the housing there is an additional transition pipe connected to the inlet pipe. The inner surfaces of the housing, of the transitional auxiliary tube, of the outlet tube and of the damping plates are coated with noise-absorbing material. The distance between the damping plates is made by increasing step on the side of the inlet pipe towards the other end of the housing, so that the distance is different between each two plates (3).

The technical nature of the utility model

The aerodynamic silencer includes a carrier housing which houses streamlined noise-absorbing elements arranged in parallel rows containing noise-absorbing material. According to the utility model, the parallel rows are at least two and the absorbent elements along their entire length are made of homogeneous material and are enclosed by noise absorbent material made of a layer of extruded polyethylene having a thickness of at least 5 (five) times greater of the thickness of the noise-absorbing elements.

According to one embodiment of the utility model, the noise absorbing elements are formed as rectangular cross-section plates arranged longitudinally on the supporting housing and at an equal distance from each other.

According to a second embodiment of the utility model, the single-row noise-absorbing elements are spaced equally apart and staggered relative to the adjacent-row elements, with all the noise-absorbing elements mounted transversely to the supporting housing. The distance between the parallel rows is less than the distance between the single-row noise-absorbing elements, which are filled with a round cross-section of PVC pipe (polyvinyl chloride).

According to a third embodiment of the utility model, the noise-absorbing elements are mounted on two opposite inner surfaces of the supporting housing, the elements of the first inner surface being staggered relative to the elements of the second inner surface of the housing. The sloping edges of each element lie in one plane at an equal distance from each other, with all the elements being formed as slabs with a rectangular cross-section.

Preferably, in all embodiments, the support body is formed by a rectangular or circular cross-section and is made of galvanized steel, with its inner surfaces covered with a layer of extruded polyethylene.

The advantages of the utility model are that the silencer is of a simplified construction, safe in operation and of extended service life, since the sound absorbing elements are the same in their entire length. They are optimally housed and have an optimal ratio of the thickness of the elements to the extruded polyethylene layer.

There is an option to choose the most suitable silencer depending on the noise level and air pressure, due to several variants of the utility model.

Description of the attached figures

Figure 1 shows a longitudinal section of a first embodiment of the utility model (linear silencer) with longitudinal arrangement of the noise absorbers.

Figure 2 is a longitudinal sectional view of a second embodiment of the utility model (stage silencer) with transversely arranged noise absorbers.

Figure 3 is a longitudinal sectional view of a third embodiment of the utility model (labyrinth silencer) with staggered noise absorber elements.

Examples of implementation of the utility model

The aerodynamic silencer according to the first embodiment as shown in FIG. 1 consists of a hollow housing 1 having a rectangular cross-section made of galvanized sheet steel, the inner surface of which is formed by a layer of extruded polyethylene. In the housing 1 there are longitudinally five noise-absorbing plates (elements) 2 of rectangular cross-section covered by a layer of extruded polyethylene 3. In this case, each row of elements 4 is formed by one noise-absorbing plate 2. The distance between each two adjacent plates 2 is the same , and the thickness of the plate 2 is five times smaller than the thickness of the extruded polyethylene layer 3.

In another embodiment, as shown in FIG. 2, in the supporting housing 1 there are noise absorbing elements made of polyvinyl chloride tubes 2 (RUS tubes), arranged in five rows. The tubes 2 contained in row 4 are staggered relative to tubes 2 of another adjacent row 4. All tubes 2 are arranged transversely to the housing 1 and are enclosed by a layer of extruded polyethylene 3 having the distance between any two adjacent elements 2 of one row 4 is the same and is greater than the distance between rows 4.

According to a third exemplary embodiment of the utility model, as shown in FIG. 3, in the supporting housing 1, the noise-absorbing elements 2 are designed as slabs with a rectangular cross-section and are installed in the two opposite inner surfaces 5 and 6 of the housing 1. The noise-absorbing elements 2 of the first inner surface 5 are staggered relative to the inner elements 2 of the second surface 6, and the bevelled edges of each element 2 lie in one plane at an equal distance from each other.

At each end of the carrier housing 1, in each embodiment, the connecting ribs 8 are formed and a layer of extruded polyethylene is applied on its inner surface.

Using the utility model

The utility model works as follows.

After attaching the silencer to the ducts of ventilation or air-conditioning systems, through the connecting ribs 8, the air flow enters the duct and enters the silencer, passing through the silencer elements 2. Due to the sound absorbing layer 3, absorption of the sound is carried out.

When the cylindrical noise-absorbing elements 2 of the polyvinyl chloride tube are transversely positioned in the housing 1, the air passes along the outer surfaces of the elements 2, the sound-absorbing material 3 is removed, and the path traversed by the airflow is extended and extended.

In the labyrinth arrangement of the noise-absorbing elements 2 in the housing 1, the air stream performing the labyrinth movement bypasses each element 2 in sequence, whose noise-absorbing layer 3 takes away more sound energy from the air-stream.

Claims (5)

1. An aerodynamic silencer comprising a carrier housing housing the streamlined noise-absorbing elements arranged in parallel rows containing noise-absorbing material, characterized in that the parallel rows (4) are at least two and the noise-canceling ones elements (2) along their entire length are made of homogeneous material and are enclosed by noise absorbing material - a layer of extruded polyethylene (3) whose thickness is at least five times greater than the thickness of the noise absorbing elements (2). 2. The silencer according to claim 1, characterized in that the noise-absorbing elements (2) are shaped as rectangular cross-sections, arranged longitudinally on the supporting housing (1) and spaced equally. The silencer according to claim 1, characterized in that the noise-absorbing elements (2) contained in one row (4) are spaced equally apart and staggered relative to the noise-absorbing elements (2) of the adjacent row (2). 4), with all elements (2) being mounted transversely to the supporting housing (1), and the distance between the parallel rows (4) is less than the distance between the noise-absorbing elements (2) of one row (4), with the noise-absorbing elements (4) 2) have a circular cross section and are made of polyvinyl chloride pipe. A silencer according to claim 1, characterized in that the noise-absorbing elements (2) are mounted on two opposite inner surfaces (5, 6) of the supporting housing (1), the elements (2) of the first inner surface (5) being staggered relative to the elements (2) of the second inner surface (6) of the housing (1), and the sloping edges (7) of each element (2) lie in the same plane at equal distance with each other, with the noise absorbing elements (2) being met like slabs with a rectangular cross-section. 5. The silencer according to claims 1 to 4, characterized in that the supporting housing (1) is formed by a rectangular or circular cross section and is made of galvanized steel, with a layer of extruded polyethylene (3) formed on its inner surfaces. . Attachment: 3 figures