SU1359444A1 - Exhaust noise muffler of internal combustion engine - Google Patents

Abstract

The invention relates to mechanical engineering and makes it possible to increase the efficiency of a noise silencer. For this, the transverse partition 7 of the partially perforated pipe 4 is placed in the perforated zone to eliminate the high-frequency sound. The perforation holes are located between the muffler cross sections that are halfway and a quarter of the length of the body with minimum hydraulic losses (the total area of the perforations of the section 5 in the pipe should be 1.5-1.7 of the pipe's cross section. The total area of the perforation of the section 6 should be 1.1-1.3 of the cross-sectional area of the pipe.To increase the efficiency of sound attenuation at resonant frequencies causing dips in the muffling, the section of pipe 4 on one side of the partition is filled with solid a length of 1 / 8L - C, where L is the length of the muffler body; C is the coefficient of dynamic elongation of the perforation portion.The oscillation of the fourth longitudinal mode is suppressed by placing a transverse perforated partition 9 in the muffler chamber and dividing the muffler chamber into two chambers whose length 5: 3 ratio, and the total area of the perforation holes 10 lies in the range of 1.2-1.6 from the cross-sectional area of the pipe 4. The opening 8 of the partition 7 is acoustically 5 5. with S (L 00 01 with 4 4 N (tpue.l

Description

The invention relates to mechanical engineering, in particular to engine building, and in particular to silencers of the output noise of an internal engine -> early.

The aim of the invention is to increase the efficiency of the silencer.

Figure 1 presents the proposed muffler, a longitudinal section; 10 of FIG. 2 is a section AA in FIG. 1, in FIG. 3 — lower intrinsic radial vibration modes of a gas volume enclosed in a silencer chamber at a resonant frequency; figure 4 - placement of the muffler elements; Figo longitudinal longitudinal proper (first to fourth) resonant vibration modes of the gas volume enclosed in the silencer chamber. ' 20

ι. 4 and 5 are indicated: L is the length of the silencer body, d is the pipe diameter; P is the pressure; C is the coefficient of dynamic elongation of the perforation site. 25 wherein the perforation holes 10 in the partition 9 can be placed at an equal distance from the body 1 and the pipe 4. In the area of the partition 7 of the pipe 4 there can be a continuous section.

With - the coefficient of dynamic elongation of the perforation is taken equal to (0.1-0.2) d _GIAR ; d _{ri <Ap} = '4F _m = where <1 _hydr - hydraulic pipe diameter; F is the cross-sectional area of the pipe; P - perimeter (circumference) of the pipe.

Silencer works as follows.

The exhaust gases enter the pipe 4 and through the perforation section 5, where. sound energy is partially dissipated into the silencer chamber, the length of which is 5 / 8L, where it expands, while losing some of the sound energy _h . Further, through the perforation holes 10 in the partition 9, where the sound energy is again partially dissipated, the exhaust silencer of the internal combustion engine contains a cylindrical body 1 with end walls 2 and 3, coaxially mounted with a partially perforated pipe 4 for supplying and discharging exhaust gases. Sections 5 and 6 of the perforation holes are located between the cross sections of the muffler, spaced from half and a quarter of the length of the housing 1 towards the end walls 2 and 3 by 0.1-0.2 pipe diameters. Inside the perforated pipe 4, a transverse partition 7 is installed, which can be made with a hole 8. A transverse partition 9 is installed in the gap (chamber) between the pipe 4 and the housing 1, dividing it into two chambers, and the perforation holes of the “pipe are made” in parallel rows.

The total area of the holes of the perforation of the section 5 of the pipe 4 can be 1.5-1.7 squares of its cross section, and the total area of the holes of the perforations of the section 6 of the pipe 1.11.3 of the area of its cross section.

The transverse septum 9 can be perforated, the ratio of the lengths of the chambers formed by the septum 9 and the walls 2, 3, can be 5: 3, and the total area of the perforation holes 10 in the septum 9 can be 1.2-1.6 of the pipe cross-sectional area 4, the gases enter the second chamber of the silencer, the length of which is 3 / 8L, where they expand and lose some of the sound energy. Finally, from this chamber the gases through the openings of the perforation section 6, where the sound energy is again partially dissipated, enter the pipe 4 and are discharged into the atmosphere y, the sound energy of gases in this case is · 35 significantly weakened.

The maximum degree of silencing can be achieved by optimizing the placement of perforation holes, the degree of perforation and the specific placement of silencer elements.

The sound of low frequencies entering the expansion chamber through the openings of the perforation section 5 is significantly reflected, while losing its energy, and to a significant extent attenuates. Partially, sound energy is spent passing through perforation holes, turning into thermal energy. The sound of the first, second, and third longitudinal ₅₀ modes is not skipped, since the extreme rows of perforation sections 5 and 6 are located at the nodes of minimum (zero) sound pressure, taking into account the dynamic increment, and the resulting resonance sound is not passed out of the chamber. The fourth longitudinal mode of sound resonance attenuates when passing through the baffle 9, since the baffle is placed in the antinode of the vibration velocity of this mode, which ensures effective sound scattering.

The sound of the first transverse resonance mode in the chamber is not transmitted due to the central placement of the pipe 4 5

The second mode of transverse resonance is not excited, since the holes 10 in the partition 9 are located near the usp of the minimum sound pressure on this form. 10

The efficiency of the silencing increases due to the amplification of the silencing in the resonator, formed by a partition 7 and a continuous section of the pipe adjacent to it. fifteen

To eliminate the transmission of high-frequency sound through the pipe 4 in the zone of its perforation, a transverse partition 7 is installed.

To increase the efficiency of noise suppression with minimal hydraulic losses, the total area of the perforation holes of section 5 in the pipe 4 should be 1.5-1.7 of the cross-sectional area of the pipe 4, since 25 outside this range one of the effects worsens by an unacceptable value. Similarly, the total area of the perforation holes of section 6 should be 1.1-1.3 of the cross-sectional area of the pipe, since otherwise the sound attenuation efficiency worsens, or the hydraulic resistance increases.

In order to increase the efficiency of sound attenuation at resonant frequencies, causing dips in the damping, the pipe section 4 on one side of the cross-section of town 7 is made continuous for a length of 40 not 1 / 8L - C.

The fourth longitudinal mode is suppressed by placing a transverse perforated partition 9 in the silencer chamber and dividing the silencer chamber into two chambers, the lengths of which are .5: 3, and the total area of the perforation holes 10 lies in the range 1.21.6 of the cross-sectional area pipes 4.

The hole 8 of the partition 7 allows you to increase the acoustic connection of the pipe 4 with the silencer chamber.

Claims (6)

one The invention relates to mechanical engineering, in particular, to engine construction, in particular, to mufflers of the noise output of an internal-combustion engine. The aim of the invention is to increase the effectiveness of the noise suppressor. Figure 1 presents the proposed muffler, a longitudinal section; 2 is a section A-A in FIG. 1, in FIG. 3 — the lowest intrinsic radial forms of oscillations of the gas volume contained in the silencing chamber at the resonant frequency; figure 4 - placement of the elements of the muffler in figure 5 the longitudinal lower proper (from first to fourth) resonant forms of oscillations of the gas volume, enclosed in the chamber of the muffler. . In Figures 4 and 5, there is indicated: L is the length of the muffler body, d is the diameter of the pipe; Р - pressure; C is the coefficient of dynamic elongation of the perforation area. The engine exhaust silencer - internal combustion contains a cylindrical body 1 with end walls 2 and 3, coaxially with which a partially perforated pipe 4 is installed for supplying and discharging exhaust gases. The portions 5 and 6 of the perforation holes are placed between the cross sections of the muffler, spaced from half and a quarter of the length of the body 1 towards the end walls 2 and 3, 0.1-0.2 of the pipe diameter. Inside the perforated pipe 4, a transverse partition 7 is installed, which can be made with an opening 8. A transverse partition 9 is installed in the gap (chamber) between the pipe 4 and the housing 1, its division into two chambers, and the holes in the perforation of the pipe are parallel to each other. The total area of perforation holes in section 5 of pipe 4 may be 1.5-1.7 across its cross section, and the total area of perforation holes in section 6 of pipe 1.1-1.3 from its cross section. The transverse partition 9 can be made perforated, the ratio of the lengths of the chambers formed by the partition 9 and the walls 2, 3 can be 5: 3, and the total area of the perforations 10 in the partition 9 can be 1.2-1.6 of the transverse area pipe section 4, ten 15 20 -, 25 359444 2 moreover, the perforation holes 10 in the partition 9 can be placed at an equal distance from the housing 1 and the pipe 4. In the area of the partition 7 of the pipe 4 there can be a continuous section. C — the coefficient of dynamic elongation of the perforation portion is assumed to be (0.1-0.2) d gmp J GIAR 4F - where is hydraulic „ pipe diameter F is the area of the cross section of the pipe; P - perimeter (length-, on the circumference) of the pipe. The muffler works as follows. Exhaust gases enter the pipe 4 and through the perforation section 5, where. the acoustic energy is partially dissipated into the silencer chamber, the length of which is 5/8 L, where the extension is 5 0 5 0 5 five 0 while tering some of the sound energy. Then, through the perforation holes 10 in the partition 9, where the acoustic energy is again partially dissipated, the gases enter the second chamber of the silencer, which is 3 / 8L in length, where part of the acoustic energy expands and loses. Finally, from this chamber, the gases through the holes in section 6 the perforations, where the sonic energy is again partially dissipated, flows into the tube 4 and is released into the atmosphere, while the sonic energy of the gases is greatly weakened. The maximum degree of damping can be achieved by optimizing the placement of the perforation holes, the degree of perforation and the specific placement of the silencer elements. The sound of the low frequencies, the entrance to the expansion chamber through the holes of the perforation section 5, is greatly reflected, while losing its energy, and to a large extent attenuates. Partially, the sonic energy is spent on the perforation through the holes, turning into thermal energy. The sound of the first, second and third longitudinal modes is not transmitted, since the extreme rows of perforation sections 5 and 6 are located at the minimum (zero) sound pressure nodes, taking into account the dynamic nature and the resulting sound resonance is not transmitted from the chamber to the outside. The fourth is the longitudinal mode of sound resonance attenuated t, the passage through the partition 9, since the partition is placed in the antinode of the vibroscope3 growth of this mode, which ensures effective dispersion of sound. The sound of the first transverse resonance mode in the chamber is not transmitted due to the central placement of the second pipe. The transverse resonance mode n is excited as the holes 10 E partition 9 placed near the nodes of the minimum sound pressure in this form. Effectiveness of silencing age 1et due to the amplification of damping in the resonator formed by the partition 7 and the solid pipe section adjacent to it. To eliminate the transmission of high-frequency sound through pipe 4, a transverse partition 7 is installed in the perforated area. Dp increase the efficiency of noise-20 cross-section muffler. at the minimum hydraulic losses, the total hole area of the perforation of section 5 in pipe 4 should be 1.5-1.7 of the cross-sectional area of pipe 4, since 25 outside this range one of the effects deteriorates by an unacceptable amount. Similarly, the total hole area of the perforation of section 6 should be 1.1-1.3 of the cross-sectional area of the pipe, because otherwise the sound attenuation efficiency will deteriorate or the flow resistance will increase. 35 In order to increase the efficiency of sound attenuation at resonant frequencies causing dips in the muffling, a section of pipe 4 on one side of the septum 7 is made solid for a length of 40 not 1 / 8L - C. The suppression of oscillations of the fourth longitudinal mode is carried out by spaced apart from half and a quarter of the length of the body towards the end walls by 0.1-0.2 of the pipe diameter. 2. The silencer according to claim 1, about tl and h a-yu y and with the fact that the transverse partition of the pipe is made with a central hole. 3. The silencer according to claims 1 and 2, which is based on the fact that the total area of perforation holes on one side of the pipe partition wall is 1.5-1.7 of its cross-sectional area. 4. A muffler according to Clause 3, characterized in that the total area of the perforation holes on the other side of the pipe partition is 1.1-1.3 of its cross-sectional area. 5. A silencer according to claims 1-4, characterized in that the transverse partition in the housing is perforated, the ratio of the lengths of the chambers is 5: 3, and the total in the muffler chamber, the cross-sectional area of the perforation holes in the perforated partition 9 and the division of the silencer chamber into two chambers, the lengths of which are 5: 3, and the total area of the holes campus is 1.2-1.6 the cross-sectional area of the pipe. 6. A silencer according to claims 1-5, characterized in that the holes 10 perforation lies in the range of 1,2-. perforations in the partition wall of the housing, 1, 6 from the cross-sectional area of the pipe 4, The opening 8 of the partition 7 allows the acoustic coupling of the pipe 4 to the silencer chamber to be enhanced. Invention Formula 1. An exhaust silencer for an internal combustion engine, comprising a cylindrical body with end walls, a coaxially partially perforated pipe for supplying and discharging exhaust gases and transverse partitions installed in the pipe and in the gap between the pipe and the case, dividing it into two chambers, with perforations the pipes are made in parallel rows, characterized in that, in order to increase efficiency, the transverse partition of the pipe is placed in the perforation zone, and the holes in the perforation of the pipe are spaced from oloviny a quarter length of the body toward the end walls 0.1-0.2 pipe diameter. 2. The silencer according to claim 1, about tl and h a-yu y and with the fact that the transverse partition of the pipe is made with a central hole. 3. The silencer according to claims 1 and 2, which is based on the fact that the total area of perforation holes on one side of the pipe partition wall is 1.5-1.7 of its cross-sectional area. 4. A muffler according to Clause 3, characterized in that the total area of the perforation holes on the other side of the pipe partition is 1.1-1.3 of its cross-sectional area. 5. A silencer according to claims 1-4, characterized in that the transverse partition in the housing is perforated, the ratio of the lengths of the chambers is 5: 3, and the total campus is 1.2-1.6 the cross-sectional area of the pipe. 6. A silencer according to claims 1-5, characterized in that the holes perforations in the bulkhead of the casing are located at equal distances from the casing and the pipe. fzg.2   fie.Z Editor M. Bandura Compiled by V.Slavnikov Tehred M. Khodanich Proofreader Shekmar Order 6127/33  Circulation 482 Subscription VNIIPI USSR State Committee for inventions and discoveries 113035, Moscow, Zh-35, Raushsk nab., 4/5 Production and printing company, Uzhgorod, st. Project, 4