JPH0844372A - Active silencer - Google Patents

Abstract

PURPOSE:To improve a silencing effect in a high frequency band largely more than heretofore in an active silencer in which a noise of a noise medium is positively silenced by a secondary sound source. CONSTITUTION:This device is composed of a microphone 41 arranged at an upstream side of a secondary sound source in a silencer space 35, a delay means 43 delaying an electric signal from the microphone 41 so that phase lag caused by the distance between the secondary sound source 39 and the microphone 41 and intrinsic phase lag of the secondary sound source 39 are dissolved, and an inversion means 47 reversing an electric signal delayed by the delay means 43 and outputting it to the secondary sound source 39. Also, this device is composed of a forward side microphone and an upstream side microphone arranged at forward and upstream of the secondary sound source 39 in a silencer space 35, an addition means adding electric signals from the forward side microphone and the upstream side microphone, and an inversion means reversing an electric signal added by the addition means and outputting it to the secondary sound source 39.

Description

Detailed Description of the Invention

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to an active silencer capable of positively silencing noise of a noise medium by a secondary sound source.

[0002]

2. Description of the Related Art Conventionally, as an active silencer that actively suppresses noise of exhaust gas by a secondary sound source,
For example, the one disclosed in Japanese Utility Model Publication No. 6-14420 is known.

FIG. 10 shows an active silencer of this type. In the figure, reference numeral 11 denotes a silencer body. The silencer body 11 is divided by a partition wall 13,
A muffling room 15 and a speaker room 17 are formed.

An exhaust pipe 19 for circulating the exhaust gas G is opened in the muffler chamber 15. Speaker room 17
A speaker 21, which is a secondary sound source that radiates sound waves, is arranged inside the muffling chamber 15.

In front of the speaker 21 in the muffling room 15,
A microphone 23 is arranged at a distance L ₁ from the speaker 21. The microphone 23 and the speaker 21 are connected via the power amplifier 25 and the inverting circuit 27.

In such an active silencer, the noise of the exhaust gas G is detected by the microphone 23, and the erasing sound having a phase opposite to the detected noise is emitted from the speaker 21, so that the so-called active muffling is performed. Done.

[0007]

However, in such a conventional active silencer, since the speaker 21 and the microphone 23 are separated by the distance L ₁ , the noise is detected by the microphone 23 before the speaker 21. Before the erasing sound is emitted, as shown in FIG. 11, the distance L
₁ causes a phase delay deg1 and the speaker 21
From when an electric signal is input to the vibration of the diaphragm,
Since a mechanical phase delay deg2 peculiar to the speaker 21 occurs, there is a problem in that a sufficient silencing effect cannot be obtained particularly in a high frequency range where the tracking characteristic of the speaker 21 deteriorates.

The present invention has been made to solve the above conventional problems, and an object of the present invention is to provide an active silencer capable of significantly improving the silencing effect in a high frequency range.

[0009]

According to another aspect of the present invention, there is provided an active muffler, wherein a secondary sound source chamber is formed adjacent to a muffler chamber in which a noise medium is circulated, and the secondary sound source chamber is provided inside the muffler chamber. In an active silencer in which a secondary sound source that emits sound waves is arranged, a microphone arranged upstream of the secondary sound source in the silencing chamber, and an electric signal from the microphone,
Delay means for delaying so as to eliminate a phase delay due to the distance between the secondary sound source and the microphone and a phase delay specific to the secondary sound source; and an electric signal delayed by the delay means for inverting Inversion means for outputting to the next sound source.

According to another aspect of the active muffler of the present invention, a secondary sound source chamber is formed adjacent to the noise canceling chamber in which the noise medium is circulated, and the secondary sound source emits sound waves into the muffler chamber. In an active silencer in which a sound source is arranged, a front microphone arranged in front of the secondary sound source in the muffling room, and an upstream side of the secondary sound source in the muffling room, and the secondary sound source. An upstream microphone disposed at a position that eliminates a phase delay due to the distance to the front microphone and a phase delay specific to the secondary sound source, an electric signal from the front microphone, and an electric signal from the upstream microphone. And an inverting means for inverting the electrical signal added by the adding means and outputting the inverted electrical signal to the secondary sound source.

[0011]

In the active silencer according to the first aspect, since the microphone is arranged on the upstream side of the secondary sound source, the phase of the noise detected by this microphone leads the phase in front of the secondary sound source, but is delayed. By means of the means, the phase of the noise detected by the microphone is delayed so as to correct the phase delay due to the distance between the secondary sound source and the microphone and the phase delay inherent to the secondary sound source, and as a result, is detected by the microphone. When the noise is located in front of the secondary sound source, the erasing sound corresponding to this noise reaches the noise and the noise is silenced.

According to another aspect of the active silencer of the present invention, an electric signal from an upstream microphone arranged upstream of the secondary sound source in the silencing room and an electric signal from a front microphone arranged in front of the secondary sound source. When the signal and the signal are added by the adding means, the phase of the added electric signal becomes such that when the noise is located in front of the secondary sound source, the erased sound corresponding to this noise reaches the noise.

That is, when the secondary sound source is operated only by the electric signal detected by the front microphone arranged in front of the secondary sound source, the phase delay due to the distance between the secondary sound source and the microphone and the characteristic of the secondary sound source are caused. And the phase lag of
There is a delay in the time when the erased sound corresponding to noise reaches noise,
When the electric signal of the upstream microphone is added to the electric signal of the front microphone, the phase detected by the upstream microphone is ahead of the front phase of the secondary sound source, so the phase of the added electric signal is When the noise is located in front of the secondary sound source, the phase of the erased sound corresponding to this noise reaches the noise.

[0014]

Embodiments of the present invention will be described below in detail with reference to the drawings. FIG. 1 shows a first embodiment of the active silencer of the present invention. In the figure, reference numeral 31 denotes a silencer body.

The muffler body 31 is divided by a partition wall 33 to form a muffler chamber 35 and a speaker chamber 37. An exhaust pipe 38 that allows the exhaust gas G to flow is opened in the muffling chamber 35.

In the speaker room 37, a speaker 39, which is a secondary sound source for radiating sound waves, is arranged in the muffling room 35. Therefore, in this embodiment, the microphone 41 is arranged upstream of the speaker 39 in the muffling chamber 35.

The position of the microphone 41 is determined by the distance L ₁ between the speaker 39 and the microphone 41 (speaker 3
9) distance in the direction of the central axis) and the phase delay deg1
The position is such that the phase advances by the phase delay amount added with the phase delay deg2 peculiar to the speaker 39.

An electric signal from the microphone 41 is supplied to the microphone 39 and the speaker 39.
1 and the phase delay deg1 caused by the distance L ₁ from the speaker 3
A delay circuit 43 for delaying so as to eliminate the phase delay deg2 peculiar to 9 is connected.

The delay circuit 43 is formed of a delay element, a filter and the like. Then, the inverting circuit 47 is connected to the delay circuit 43 via the power amplifier 45.

The power amplifier 45 amplifies the electric signal from the delay circuit 43. The inverting circuit 47 is the power amplifier 4
The electric signal from 5 is inverted and output to the speaker 39.

In the active silencer described above, the speaker 39
Since the microphone 41 is arranged on the upstream side of the speaker 41, the phase of the noise detected by the microphone 41 advances from the phase in front of the speaker 39. However, as shown in FIG. 2, the noise is detected by the microphone 41 by the delay circuit 43. The phase of the generated noise is delayed so as to correct the phase delay deg1 caused by the distance L ₁ between the speaker 39 and the microphone 41 and the phase delay deg2 peculiar to the speaker 39. As a result,
When the noise detected by the microphone 41 is located in front of the speaker 39, the erased sound corresponding to this noise reaches the noise and the noise is silenced.

In FIG. 3, as shown in FIG. 10, a microphone 23 is arranged at a front center position of the speaker 21 with a distance L ₁ from the speaker 21.
3 shows the phase delay when the electric signal from 3 is inverted by the inverting circuit 27 and the speaker 21 is actually operated.
The horizontal axis shows the frequency of the exhaust noise detected by the microphone 23, and the vertical axis shows the phase delay at that frequency. This phase delay is caused by the distance L ₁ between the speaker 21 and the microphone 23. Phase delay and speaker 2
The phase delay is the sum of the phase delays of 1 and 1, that is, the target phase correction amount.

The speakers 21 and 39 and the microphones 23 and 41 are exactly the same. FIG.
Indicates a phase difference between the microphone 23 arranged in front of the speaker 21 and the microphone 41 arranged upstream of the speaker 39, and is detected by the microphone 41 on the horizontal axis. The vertical axis of the frequency of the generated exhaust noise is taken as the phase lead at that frequency.

FIG. 5 shows the target position correction amount shown in FIG.
The required phase correction amount is calculated based on the phase difference between the microphone 23 arranged in front of the speaker 21 and the microphone 41 arranged upstream of the speaker 39 shown in FIG. 4, and the necessary phase correction amount is corrected. , Shows the result of performing the phase correction by changing the delay control multiplier of the delay circuit 43, the solid line shows the target position correction amount, and the broken line shows the correction result.

FIG. 6 shows the muffling characteristics when the correction shown in FIG. 5 is carried out. The solid line shows the muffling volume of the conventional active silencer shown in FIG. 10, and the broken line shows the active volume of this embodiment. It shows the silence volume of the muffler, especially 200Hz-1000H
It can be seen that the muffling effect in the high frequency range of z is significantly improved compared to the conventional one.

However, in the active silencer described above,
Detected by the microphone 41 by the extension circuit 43
The phase of noise depends on the distance between the speaker 39 and the microphone 41.
Distance L ₁Phase delay deg1 caused by the
Since it is delayed so as to correct the phase delay deg2,
As shown in, the noise suppression effect in the high frequency range is
It can be greatly improved from now on.

FIG. 7 shows a second embodiment of the active silencer of the present invention. In this embodiment, a front microphone 49 is arranged in front of the center of the speaker 39 in the silencer room 35. There is.

An upstream microphone 51 is arranged upstream of the speaker 39 in the muffling room 35. The upstream microphone 51, a phase delay deg1 due to the distance L ₁ between the speaker 39 and the front microphone 49,
The speaker 39 is arranged at a position where the phase delay deg 2 peculiar to the speaker 39 is eliminated, that is, at a position at a distance L ₂ from the front microphone 49.

The optimum position of this distance L ₂ changes depending on the temperature of the exhaust gas, which is a noise medium. For example, from the speaker 39 to the front microphone 49.
Distance L ₁ to 50 mm, phase delay peculiar to speaker 39
When deg2 is 0.36 Hz, the optimum distance is as shown in FIG.

In FIG. 8, the temperature of the exhaust gas is plotted on the horizontal axis and the distance L ₂ is plotted on the vertical axis. In this embodiment, the temperature L _{2 which} the exhaust gas normally has is set as the distance L 2.
In consideration of the temperature of 00 to 300 ° C, 250 mm is set.

In FIG. 7, reference numeral 53 represents an adder circuit for adding the electric signal from the front microphone 49 and the electric signal from the upstream microphone 51. This adder circuit 53 has an inverting circuit 5 via a power amplifier 55.
Connected to 7.

The power amplifier 55 amplifies the electric signal from the adder circuit 53. The inverting circuit 57 includes the power amplifier 5
The electric signal from 5 is inverted and output to the speaker 39.

In the above-described active silencer, an electric signal from the upstream microphone 51 arranged upstream of the speaker 39 in the muffler chamber 35 and an electric signal from the front microphone 49 arranged in front of the speaker 39. When the signal and the signal are added by the adder circuit 53, the phase of the added electric signal becomes such that when the noise is located in front of the speaker 39, the erased sound corresponding to this noise reaches the noise.

That is, when the speaker 39 is operated only by the electric signal detected by the front microphone 49 arranged in front of the speaker 39, the phase delay deg1 caused by the distance L ₁ between the speaker 39 and the microphone 49 and the speaker Due to the phase delay deg2 unique to 39, the time when the erased sound corresponding to the noise reaches the noise is delayed, but when the electrical signal of the upstream microphone 51 is added to the electrical signal of the front microphone 49, the upstream microphone 51 detects it. Since the phase of the added electric signal is ahead of the phase in front of the speaker 39, the phase of the added electric signal causes noise in the speaker 3.
When located in front of 9, the phase of the erased sound corresponding to this noise reaches the noise.

Also in the above-described active silencer, as in the first embodiment, the silencing effect in the high frequency range can be greatly improved as compared with the conventional one. In the above-described embodiment, an example in which the sound is muted by only one speaker 39 has been described, but the present invention is not limited to this embodiment, and for example, the one speaker 39 lacks the sound volume. For example, as shown in FIG.
A pair of speakers 39 may be arranged on both sides of 9.

Further, in the above-mentioned embodiment, an example in which the present invention is applied to the reduction of exhaust noise of an engine or the like has been described, but the present invention is not limited to such an embodiment, and for example, the inside of a duct is It can be widely applied to reduce noise from circulating noise media.

[0037]

As described above, in the active silencer according to the first aspect, since the microphone is arranged on the upstream side of the secondary sound source, the phase of the noise detected by this microphone is equal to that of the secondary sound source. Although it advances from the front phase, the delay means delays the phase of the noise detected by the microphone so as to correct the phase delay due to the distance between the secondary sound source and the microphone and the phase delay peculiar to the secondary sound source. , As a result, when the noise detected by the microphone is located in front of the secondary sound source, the erasing sound corresponding to this noise reaches the noise, and the noise is silenced. It can be improved significantly.

According to another aspect of the active silencer of the present invention, the electric signal from the upstream microphone arranged upstream of the secondary sound source in the silencing room and the electric signal from the front microphone arranged in front of the secondary sound source. When the signal and the signal are added by the adding means, the phase of the added electric signal becomes such that when the noise is positioned in front of the secondary sound source, the erased sound corresponding to this noise reaches the noise, so that the high frequency range There is an advantage that the sound deadening effect in can be significantly improved compared to the conventional one.

[Brief description of drawings]

FIG. 1 is a circuit diagram showing a first embodiment of an active silencer of the present invention.

FIG. 2 is an explanatory diagram showing correction of a phase delay due to a distance between a secondary sound source and a microphone and a phase delay unique to the secondary sound source.

FIG. 3 is an explanatory diagram showing a relationship between a frequency and a target position correction amount.

FIG. 4 is an explanatory diagram showing a relationship between frequency and phase difference.

FIG. 5 is an explanatory diagram showing the relationship between frequency and phase correction amount.

6 is an explanatory diagram showing a silencing characteristic of the active silencer of FIG. 1. FIG.

FIG. 7 is a circuit diagram showing a second embodiment of the active silencer of the present invention.

FIG. 8 is an explanatory diagram showing the relationship between temperature and distance L ₂ .

FIG. 9 is an explanatory diagram showing a third embodiment of the active silencer of the present invention.

FIG. 10 is a circuit diagram showing an example of a conventional active silencer.

FIG. 11 is an explanatory diagram showing a phase delay due to the distance between the secondary sound source and the microphone and a phase delay unique to the secondary sound source.

[Explanation of symbols]

 31 silencer body 33 partition wall 35 silencer room 37 speaker room 39 speaker 41 microphone 43 delay circuit 47, 57 inversion circuit 49 front microphone 51 upstream microphone 53 adder circuit

Claims (2)

[Claims] 1. A secondary sound source chamber (37) is formed adjacent to a silencing chamber (35) through which a noise medium is circulated, and inside the secondary sound source chamber (37) is located inside the silencing chamber (35). An active silencer in which a secondary sound source (39) for radiating sound waves is arranged, comprising a microphone (41) arranged upstream of the secondary sound source (39) in the silencing chamber (35), Delay the electric signal from the microphone (41) so as to eliminate the phase delay caused by the distance between the secondary sound source (39) and the microphone (41) and the phase delay specific to the secondary sound source (39). An active silencer characterized by having a delaying means (43) for activating and an inverting means (47) for inverting the electric signal delayed by the delaying means (43) and outputting it to the secondary sound source (39). . 2. A secondary sound source chamber (37) is formed adjacent to a silencing chamber (35) in which a noise medium is circulated, and inside the silencing chamber (35) is formed in the secondary sound source chamber (37). An active silencer in which a secondary sound source (39) that emits sound waves is arranged, comprising: a front microphone (49) arranged in front of the secondary sound source (39) in the silencing chamber (35); The secondary sound source (39) and the secondary sound source (39) upstream of the secondary sound source (39) and the phase delay due to the distance between the secondary sound source (39) and the front microphone (49). 39) Addition for adding an electric signal from the upstream microphone (51) arranged at a position for eliminating the inherent phase delay and the electric signal from the front microphone (49) and the electric signal from the upstream microphone (51). Means (53) and the addition means (53) Active silencer, characterized in that it comprises an inverting means (57) for outputting the inverted the secondary source (39) an electric signal.