RU198564U1 - Soundproof ventilation device - Google Patents

Abstract

The utility model relates to the field of construction and can be used to reduce the noise level penetrating into apartments through window openings. The device is formed by a frame with a vertical impost, a vertical ventilation duct with an inlet limited by an air intake and an outlet equipped with a cover, the air intake is made in the form L-shaped profile, fixed on the side frame of the frame and facing the impost so that the inlet is directed parallel to the plane of the window, while the cover of the outlet of the ventilation duct from the inside is equipped with a noise-absorbing element located along the entire height of the duct in the form of a hollow perforated body with an internal partition and filling with sound-absorbing material. The technical result is to provide the possibility of adapting the frequency response of the absorption of acoustic noise by the sound-absorbing cassette to the real acoustic situation on the street. 8 p.p. f-ly, 3 dwg

Description

The utility model relates to the field of construction and can be used to reduce the noise level penetrating into apartments through window openings.

A noise-insulating ventilation device is known from the prior art [RF Patent PM No. 4326, E06B 5/20. Noise-protective ventilation device // Agafonov L.E., Krasnevsky B.V., Leibov L.V., Anikin V.A. Publ .: 16.06.1997], which includes a window frame with a vertical impost, a vertical ventilation duct with an inlet limited by an air intake and an outlet equipped with a cover, characterized in that the ventilation duct is located between the impost and the side frame of the frame, and the air intake is made in in the form of an L-shaped profile fixed on the side frame of the frame and facing the impost so that the inlet is directed parallel to the plane of the window, while the cover of the outlet of the ventilation duct is equipped from the inside with a noise-absorbing element located along the entire height of the duct, made in the form of a hollow perforated body, filled with sound-absorbing material.

The disadvantage of the device is the inability to adapt the frequency response of the sound-absorbing cassette to the conditions of a real noise environment.

The problem to be solved by the claimed device is to provide the possibility of adapting the frequency response of the absorption of acoustic noise by a sound-absorbing cassette to the real acoustic situation in the street area.

This goal is achieved due to the fact that the soundproof ventilation device, which includes a window frame with a vertical mullion, a vertical ventilation duct with an inlet bounded by an air intake and an outlet equipped with a cover, while the ventilation duct is placed between the mullion and the side frame of the frame, and the air intake is made in the form of an L-shaped profile, fixed on the side frame of the frame and facing towards the impost so that the inlet is directed parallel to the plane of the window, while the cover of the outlet of the ventilation duct from the inside is equipped with a noise-absorbing element located along the entire height of the channel, made in the form of a hollow of the perforated body filled with sound-absorbing material, an internal partition is additionally included, installed inside the perforated body so as to form a sealed connection with the body walls.

Additionally, the perforation on the body of the noise absorbing element can be made in the form of circular holes.

Additionally, the perforation on the body of the noise absorbing element can be made in the form of holes of complex shape.

Additionally, the perforation on the body of the noise absorbing element can be in the form of vertically oriented slot gaps.

Additionally, the perforation on the body of the noise absorbing element can be in the form of horizontally oriented slot gaps.

Additionally, the perforation on the body of the noise absorbing element can be in the form of oriented fan-shaped slotted gaps.

, где d - диаметр отверстия, м;

- резонансная частота, Гц; L - расстояние между отверстиями, м; h - расстояние между внутренними поверхностями перфорированного корпуса и внутренней перегородкой, м;

- толщина стенки кассеты, м; с - скорость звука в воздухе при 20°С, обеспечить требуемый спектр поглощаемых частот.Additionally, the dimensions of the round perforations and the distance between them are determined in such a way that, in accordance with the dependence

, where d is the hole diameter, m;

- resonant frequency, Hz; L is the distance between the holes, m; h is the distance between the inner surfaces of the perforated body and the inner partition, m;

- wall thickness of the cassette, m; с - speed of sound in air at 20 ° С, to provide the required spectrum of absorbed frequencies.

где b - ширина щели, м; L - расстояние между отверстиями, м; h - расстояние между внутренними поверхностями перфорированного корпуса и внутренней перегородкой, м;

- толщина стенки кассеты, м; с - скорость звука в воздухе при 20°С, обеспечить требуемый спектр поглощаемых частот.Additionally, the dimensions of the slotted perforations and the distance between them are determined in such a way that, in accordance with the dependence

where b is the slot width, m; L is the distance between the holes, m; h is the distance between the inner surfaces of the perforated body and the inner partition, m;

- wall thickness of the cassette, m; с - speed of sound in air at 20 ° С, to provide the required spectrum of absorbed frequencies.

где h - расстояние между внутренними поверхностями перфорированного корпуса и внутренней перегородкой, м; b - ширина щели, м;

- резонансная частота, Гц; L - расстояние между щелями, м;

- толщина стенки кассеты, м; с - скорость звука в воздухе при 20°С, обеспечить требуемый спектр поглощаемых частот.Additionally, the depth of the panel body is selected in such a way that, in accordance with the dependence

where h is the distance between the inner surfaces of the perforated body and the inner partition, m; b — slot width, m;

- resonant frequency, Hz; L is the distance between the slots, m;

- wall thickness of the cassette, m; с - speed of sound in air at 20 ° С, to provide the required spectrum of absorbed frequencies.

The technical result, provided by the given set of features, is to ensure the possibility of adapting the frequency response of the absorption of acoustic noise by the noise-absorbing element to the real acoustic situation in the street area.

In FIG. 1 shows a general view of the device from the room, FIG. 2 - section A-A of Fig. 1 in the closed position of the device, FIG. 3 - the same in ventilation mode.

The noise-protective ventilation device includes a window frame 1 with a vertical impost 2. Between the impost 2 and the frame 1 there is a vertical ventilation duct 3 with an inlet 4 directed parallel to the window plane, limited by an air intake 5 and an outlet 6 equipped with a cover 7. The air intake 5 is made in the form of D -shaped profile fixed on the side post of the frame 1 and facing the impost 2. The cover 7 of the outlet 6 can be equipped from the inside with a sound-absorbing element consisting of a hollow perforated body 8 with an internal partition 9 installed in such a way as to form a sealed compound. The inner volume of the housing 8 can be filled with sound-absorbing material 10. The sound-absorbing element is located along the entire height of the ventilation duct 3.

The device works as follows.

In the ventilation mode, the cover 7 is open, air from the outside through the inlet 4, limited by the L-shaped air intake 5, enters the ventilation duct 3, makes a turn in it and passes into the room. Due to the presence of a turn in the channel 3 and the sound-absorbing element on the cover 7, some attenuation of the noise level occurs.

The presence of perforations on the walls of the perforated housing 8 in combination with the baffle 9, hermetically connected to the walls of the housing, forms a system known as a Helmholtz resonator, which has the property of absorbing an acoustic wave.

Perforations can be complex, round or slotted. Depending on the shape of the holes, different formulas are used to determine the natural frequency of the resonator.

резонатора Гельмгольца для случая круглых отверстий определяется выражениемResonant frequency

the Helmholtz resonator for the case of round holes is determined by the expression

for the case of making holes in the form of slits - by the expression

- резонансная частота, Гц; S - площадь сечения отверстия, м² (S=π⋅d²); h - расстояние между внутренними поверхностями крышки и внутренней перегородки, м; b - ширина щели, м; L - расстояние между щелями, м;

- глубина щели, м; d - диаметр отверстия, м; с - скорость звука в воздухе при 20°С [Булкин В.В., Беляев В.Е., Сергеев В.Н. Конструкторские расчеты элементов РЭС в условиях механических и акустических воздействий: Учеб. пособие / Под ред. В.В. Булкина. - Муром: ИПЦ МИ ВлГУ, 2004. - 132 с. (стр. 66)]. Проведя несложные преобразования, получим выражения для вычисления одного из определяемых параметров при заданных остальных, например -

для случая щелевых отверстий,

- для случая круглых отверстий.Where

- resonant frequency, Hz; S is the sectional area of the hole, m ² (S = π⋅d ² ); h is the distance between the inner surfaces of the cover and the inner partition, m; b — slot width, m; L is the distance between the slots, m;

- slot depth, m; d - hole diameter, m; c - the speed of sound in air at 20 ° C [Bulkin V.V., Belyaev V.E., Sergeev V.N. Design calculations of radioelectric elements under mechanical and acoustic influences: Textbook. allowance / Ed. V.V. Bulkin. - Murom: IPC MI VlGU, 2004 .-- 132 p. (p. 66)]. Having carried out simple transformations, we obtain expressions for calculating one of the parameters to be determined for the given others, for example -

for the case of slotted holes,

- for the case of round holes.

или

а также аналогичные.Since in the case shown in FIG. 2 and FIG. 3 the position of the internal partition inside the body forms a profile of variable depth, the expressions necessary for calculating one of the parameters to be determined, given the rest, are also found from (1) or (2), for example

or

as well as similar ones.

The choice of the parameters of the holes, the thickness of the walls of the cassette, and other sizes included in the relations (1) and (2) will provide an opportunity to change the frequency response of the absorption of acoustic noise, to adapt the device to the real acoustic noise environment.

The presence of sound-absorbing material 10 inside the housing 8 also creates additional sound absorption.

Sources of information

1. RF patent PM No. 4326, E06B 5/20. Noise-protective ventilation device // Agafonov L.E., Krasnevsky B.V., Leibov L.V., Anikin V.A. Publ .: 16.06.1997.

2. Bulkin V.V., Belyaev V.E., Sergeev V.N. Design calculations of radioelectric elements under mechanical and acoustic influences: Textbook. allowance / Ed. V.V. Bulkin. - Murom: IPC MI VlGU, 2004 .-- 132 p.

Claims (9)

1. Soundproof ventilation device, including a window frame with a vertical mullion, a vertical ventilation duct with an inlet bounded by an air intake and an outlet equipped with a cover, while the ventilation duct is located between the mullion and the side frame of the frame, and the air intake is made in the form of an L-shaped profile, fixed on the side post of the frame and facing the impost so that the inlet is directed parallel to the plane of the window, while the cover of the outlet of the ventilation duct from the inside is equipped with a sound-absorbing element located along the entire height of the duct, made in the form of a hollow perforated body filled with sound-absorbing material, characterized in that an internal partition is additionally installed inside the perforated body, installed in such a way as to form a tight connection with the body walls. 2. The noise-protective ventilation device according to claim 1, characterized in that the perforation on the perforated body can be made in the form of round holes. 3. The noise-proof ventilation device according to claim 1, characterized in that the perforation on the perforated body can be made in the form of holes of complex shape. 4. The noise-protective ventilation device according to claim 1, characterized in that the perforation on the perforated body may have the form of vertically oriented slotted gaps. 5. The noise-protective ventilation device according to claim 1, characterized in that the perforation on the perforated body can have the form of horizontally oriented slot gaps. 6. The noise-protective ventilation device according to claim 1, characterized in that the perforation on the perforated body can be in the form of oriented fan-shaped slotted gaps. 7. A noise-protective ventilation device according to claim 2, characterized in that the dimensions of the round perforations and the distance between them are determined in such a way that, in accordance with the dependence

where d is the hole diameter, m;

- resonant frequency, Hz; L is the distance between the holes, m; h is the distance between the inner surfaces of the wall and the partition inside the perforated body, m;

- wall thickness of the cassette, m; с - speed of sound in air at 20 ° С, to provide the required spectrum of absorbed frequencies. 8. Noise-proof ventilation device according to PP. 3, 4, 5, characterized in that the dimensions of the slot-shaped perforations and the distance between them are determined in such a way that, in accordance with the dependence

where b is the slot width, m; L is the distance between the holes, m; h is the distance between the inner surfaces of the wall and the partition inside the perforated body, m;

- wall thickness of the cassette, m; с - speed of sound in air at 20 ° С, to provide the required spectrum of absorbed frequencies. 9. Soundproof ventilation device according to PP. 3, 4, 5, characterized in that the depth of the panel body is selected in such a way that, in accordance with the dependence

where h is the distance between the inner surfaces of the wall and the partition inside the perforated body, m; b — slot width, m;

- resonant frequency, Hz; L is the distance between the slots, m;

- wall thickness of the cassette, m; с - speed of sound in air at 20 ° С, to provide the required spectrum of absorbed frequencies.

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