JP3655006B2 - Active silencer - Google Patents

Description

[0001]
BACKGROUND OF THE INVENTION
  The present invention introduces, for example, exhaust gas from an internal combustion engine (such as a marine engine) as a noise source, generates sound waves having a phase opposite to that of a noise wave generated from such a noise source, and joins the noise wave. In the active silencer that silences sound, it is possible to cope with the case where the noise includes low-level sound that is difficult to mute, to ensure the effective amplitude of the speaker, to increase the speaker volume, or to respond to changes in the state of the noise source Configuration that enhances the silencing effect by providing a means to perform the operation, and unstable control of the device due to a failure of the speaker, etc.YesIt relates to a configuration for early discovery.
[0002]
[Prior art]
  Conventionally, an active silencer that takes in noise and silences it by combining artificial antiphase sound generated by a speaker with this noise is known in Japanese Patent Laid-Open No. 7-319481. It is interposed in the exhaust pipe of the internal combustion engine.
  That is, the noise is converted into an electrical signal through a noise detection means (source microphone) that monitors the noise, and the noise is input to a controller for controlling the voltage to the speaker, and a sound having a phase opposite to that of the monitored signal is generated from the speaker. It is. The noise includes various frequency components, each having various levels. If the level for each frequency component in the sound generated from the speaker is analyzed, the noise is proportional to the noise.
[0003]
  For example, in noise, the frequency component f_n When the level of the frequency is particularly high, the frequency component f is also present in the speaker sound._n The level of is particularly high. The volume (output level) of the sound generated by the speaker can be adjusted by the controller, and a mute detection means (error microphone) is provided as a monitor to check the mute effect after the speaker sound is combined with the noise. The output level of the controller is controlled based on the monitoring result, and the speaker volume control is performed. In addition, before the noise is combined with the speaker sound, a technique for correcting the noise to a certain sound range by passing the noise through a sound adjusting device such as a band pass filter to the extent that the noise reduction effect by the speaker sound is improved is also known. .
[0004]
[Problems to be solved by the invention]
  In a conventional active silencer, the noise may contain low-level frequency components that cannot be detected by the source microphone due to the location of the source microphone and the like. The level of the frequency component in the sound generated from the speaker cannot be appropriately controlled, and the speaker sound does not include the sound of the frequency component, and the sound of the frequency component in the noise remains unmuted. It will end up. In order to generate sound even with such low-level frequency components from the speaker, it is necessary to have a technology that amplifies the frequency components to such an extent that it can be monitored with the source microphone. There wasn't.
[0005]
  In addition, when using an active silencer to mute the exhaust noise of an internal combustion engine, etc., when the internal combustion engine is started up or accelerated (transient), the state of the level of the frequency component contained in the noise or the overall noise The level of is different from the steady state. For example, the convergence coefficient (coefficient for converging the output level for speaker control of the controller to the optimum value) set to mute during steady operation is the set value for rapidly changing noise in transient conditions (eg during startup) Becomes larger, and the result is that the sound is increased.
  In addition, with a small convergence coefficient corresponding to the transient state, it takes too much time to converge the noise (convergence of the speaker sound to the optimum value) during steady operation. Conventionally, there has been no technology for quickly detecting the transition time from the transient state of the internal combustion engine to the steady operation state and adjusting the speaker sound.
[0006]
  In addition, the silencing effect is reduced as the silencing control becomes unstable due to a failure of the speaker or the like. As a stage before falling into such a situation, a situation occurs in which an increase in sound is recognized after mute for the level of a certain frequency component in the noise or the level of the entire noise.
  If this can be detected, attention can be paid to the instability of control of the device, such as a speaker failure, etc., but improvement work can be done quickly. There wasn't.
[0007]
[Means for Solving the Problems]
  The present invention uses the following means in order to solve the above problems.
  2. An active silencer that takes in a noise wave, generates a sound wave having an opposite phase from the speaker, joins the noise wave, and silences the noise. A detection unit and a mute detection unit that detects the sound after mute and converts it into an electrical signal, and the detection signal of both detection units is input to the controller for voltage control of the speaker. Among each frequency component in the signal, an equalizer mechanism is provided for amplifying a component that does not reach a certain level to a certain level, and when a frequency component having no silencing effect is recognized by the detection signal of the silencing detection unit,If the difference with the maximum level frequency component is calculated and this exceeds the set reference difference,The amplification is adjusted by the equalizer function.
[0008]
  In claim 2,The active silencer according to claim 1,When the noise source exhibits a transient state in which the noise level increases or decreases and a steady state in which a certain level of noise is generated, a coefficient for converging the speaker control output level of the controller to the optimum value is used for the transient state. And for the steady state, the coefficient is selected by determining whether it is a transient state or a steady state based on the rate of change in the detection level of the noise detector.
[0009]
  In claim 3,The active silencer according to claim 1,The noise detection unit and the mute detection unit are provided with means for extracting a specific frequency component, and a sound increase occurring due to control instability is detected by comparing the level of the frequency component extracted from both detection units. It is comprised as follows.
[0010]
  In claim 4,The active silencer according to claim 1,The detection signal level of the noise detection unit is substituted into a level attenuation function set based on the distance to the mute detection unit position and the state of the noise source, and this value is compared with the detection signal level of the mute detection unit. Thus, the sound increase occurring due to the unstable control is detected.
[0011]
DETAILED DESCRIPTION OF THE INVENTION
  Embodiments of the present invention will be described with reference to the accompanying drawings.
  FIG. 1 is a schematic diagram of an active silencer having a sound adjuster 3 and a diagram showing the state of level correction, and FIG. 2 is a schematic diagram of an active silencer having an equalizer in the source microphone SM and a state of level correction by the equalizer. FIGS. 3A and 3B are a schematic diagram of the active silencer, and a diagram showing a state of level correction by an equalizer in consideration of a difference between the highest frequency component in the detection signal of the source microphone SM and a frequency component that cannot be silenced. .
[0012]
  4 is a diagram showing a state of level correction by an active silencer and a stepped equalizer as in the schematic diagram, and FIG. 5 is a diagram showing a state in which the displacement of the speaker S is corrected by connecting the front and rear through a communication pipe 5. FIG. 6 is a diagram showing a state in which the speaker box 5 and the cooling box 7 are communicated to correct the speaker S, and FIG. 7 is a graph showing the relationship between the silence level and the convergence coefficient in the transient state and the steady state of the engine. FIG. 8 is a flowchart of the speaker sound control of the active silencer based on the selection of the convergence coefficient based on the determination between the transient state and the steady state.
[0013]
  FIG. 9 is a diagram showing a sound increase detection method by extracting and comparing specific frequency components from detection signals of the source microphone SM and error microphone EM, and FIG. 10 shows the attenuation state of the source microphone SM detection signal level as a function of distance and driving. FIG. 11 is a flowchart showing a sound increase detection method estimated from the state and compared with the detection signal level of the error microphone EM, FIG. 11 is a sound increase detection flowchart according to the method of FIG. 10, and FIG. It is a figure which shows the failure detection method of the speaker by this.
[0014]
  FIG. 13 is a graph showing the detection criteria of speaker failure in the method of FIG. 12, FIG. 14 is a flowchart of speaker failure detection by the method of FIGS. 12 and 13, and FIG. 15 is a diagram of the speaker by providing a humidity sensor before and after the speaker. FIG. 16 is a graph showing the failure detection criteria in the method of FIG. 15, FIG. 17 is a flowchart of speaker failure detection by the method of FIGS. 15 and 16, and FIG. 18 is detection of the error microphone EM. FIG. 19 is a flowchart showing a speaker failure detection method according to the method of FIG. 18. FIG. 19 shows a speaker failure detection method by extracting a high frequency component from a signal and comparing it with a reference value.
[0015]
  FIG. 20 is a graph showing speaker failure detection criteria in the speaker failure detection method based on comparison between the controller output and its reference value, and FIG. 21 is a speaker failure detection flowchart based on detection of the controller output based on the detection criteria shown in FIG. FIG. 22 is a flowchart of a speaker failure detection in which the method of FIGS. 18 and 19 and the method of FIGS. 20 and 21 are combined. FIG. 23 is a diagram showing a method of detecting a speaker failure by providing a speaker displacement measuring means. FIG. 24 is a graph showing speaker failure detection criteria in the method of FIG. 23, FIG. 25 is a flowchart of speaker failure detection according to the methods of FIGS. 23 and 24, and FIG. 26 also includes a process of determining a set reference value from operating conditions. It is a speaker failure detection flowchart.
[0016]
  First, a schematic overall configuration of the active silencer will be described with reference to FIG. The main pipe 1 is piped as a pipe through which a noise wave propagates, and this is integrated with the exhaust pipe when used, for example, to mute the exhaust sound of an internal combustion engine. In FIG. 1, the speaker S is directly opposed to the main tube 1, and a portion where the front surface of the speaker S is opposed to the main tube 1 is a sound wave interference unit 2. In the embodiment of FIG. 5 and the like, the front surface of the speaker S faces the branch pipe 4, and the branch pipe 4 joins the sound wave interference unit 2 of the main pipe 1. In the sound wave interference unit 2, the noise wave and the antiphase sound wave from the speaker S interfere with each other to cancel each other and mute. The sound generated from the speaker S is controlled by the output voltage control of the controller, and a source microphone SM as a noise detection unit for detecting noise before mute is provided on the upper side of the sound wave interference unit 2 in the main pipe 1. An error microphone EM as a mute detection unit for detecting a muffled sound is arranged on the lower side than the sound wave interference unit 2, and each detected sound is converted into an electric signal and input to the controller. Is done. An equalizer is interposed in the signal path from the source microphone SM to the input unit of the controller, which will be described later.
[0017]
  In such a configuration, as a basic silencing control method, the detection level of the source microphone SM and the detection level of the error microphone EM are compared by the controller, the silencing effect is recognized, and the output level to the speaker S To adjust the volume of the speaker S to the volume at which the silencing effect is most enhanced.
[0018]
  The signal level of the source microphone SM input to the controller has a certain level range SZ necessary for the controller to send a signal necessary for mute. That is, the frequency component f indicating the peak in the signal detected by the source microphone SM._L The condition that the sound can be silenced is that the level is within a level range SZ (for example, 20 to 30 dB) with a maximum value of. For example, as shown in FIG. 1A, the frequency component f indicating the peak_L The frequency component f that does not reach the level range SZ compared to_n Is included. In this case, the frequency component f that does not reach the level region SZ as shown in FIG._n No silencing effect.
[0019]
  Therefore, as shown in FIG. 1, it is conceivable that a sound adjuster 3 such as a band-pass filter is provided on the upper side of the position where the source microphone SM of the main pipe 1 is disposed. This attenuates sound in a certain frequency range in the noise. For example, a high level (peak) frequency component f as seen in (a)_L Assume that a bandpass filter set to attenuate sound in a certain frequency range including is provided. During noise, a high-level frequency component f that exceeds the silencing range f_L However, when the signal passes through the band pass filter, as shown in (c), the frequency component f_L Is attenuated. As a result, the frequency component f_L The low-level frequency component f in the noise that has not reached the level range SZ from_n However, in the noise signal input from the source microphone SM, the frequency component f before the level signal SZ is entered._L The difference in level with the speaker becomes smaller, and the sound can be sufficiently muted with speaker sound. Thus, by adjusting the noise so that it enters the level range SZ by the sound adjuster 3 upstream from the source microphone SM, the signal monitored by the source microphone SM is also in the state of (c), and the speaker sound and By passing the sonic wave interference unit 2 that joins, the monitor signal of the error microphone EM also becomes as shown in (d), and the low-level frequency component f_n There is also a silencing effect.
[0020]
  However, there is a case where a certain frequency component cannot be sufficiently detected depending on the position of the source microphone SM which is a monitor for speaker sound control although it is not so low in noise. As shown in FIG. 2A, the low frequency component f lower than the lowest level (the lowest level of the level region SZ) that can generate speaker sound in the signal detected by the source microphone SM._m Or f_n The frequency component f of the speaker S_m And f_n Cannot be generated, and the muffled sound is added to the frequency component f as shown in (b)._m ・ F_n The sound remains without being completely silenced, and this is quite annoying. Therefore, the frequency component f from the speaker S_m ・ F_n The frequency component f in the source microphone SM is obtained using an equalizer to such an extent that the sound of_m ・ F_n Amplify.
[0021]
  The equalizer raises all frequency components in the detection signal of the source microphone SM to a certain reference level or higher. By using this, only the low-level frequency components that have not reached the reference level are used as the reference level. It can be amplified to approach That is, in the case of FIG. 2, by operating the equalizer, the frequency component f below the reference level found in (a)._m ・ F_n Only the frequency component having a level equal to or higher than the reference level is kept as it is, and the detection signal of the source microphone SM is in a state as shown in (c).
[0022]
  The detection result of the error microphone EM is used for the determination of amplification by the equalizer. That is, as shown in FIG. 2B, in the detection signal of the error microphone EM, the frequency component f for which the silencing effect is not improved._m ・ F_n Is recognized, the equalizer is made to function, and the frequency component f in the detection signal of the source microphone SM_m ・ F_n Amplify. This amplification is performed in stages, and is gradually amplified while confirming the silencing effect by the detection signal of the error microphone EM. Thus, as shown in (d), in the detection signal of the error microphone EM, the frequency component f_m ・ F_n The noise reduction effect can be seen.
[0023]
  It should be noted that in the amplification by the equalizer, the adjustment of the amplification amount is a problem. If the amplification is excessive, the sound is increased and the sound is diverged. Therefore, as a guideline for setting the amplification amount, as shown in FIG. 3B, the frequency component f in which the silencing effect is not recognized in the detection result of the error microphone EM._m ・ F_n (A) The maximum level frequency component f is detected by the detection signal of the source microphone SM shown in FIG._L When this exceeds a set reference difference (for example, 30 dB), as shown in (c), the equalizer uses a low-level frequency component f._m ・ F_n Is amplified.
  This results in limiting the amount of amplification. That is, the low-level frequency component f_m ・ F_n In the process of amplifying the frequency component f_L If the difference between and becomes the reference value, the amplification is stopped at that point. This amplification is also carried out step by step, and when a frequency component that cannot be silenced still remains after seeing the detection result (b) of the error microphone EM, amplification is further performed by an equalizer as shown in (c) to obtain a final silencing effect. (D) It is amplified to the stage shown in the figure.
[0024]
  The active silencer shown in FIG. 4 combines the functions shown in FIGS. 2 and 3 and performs amplification by the equalizer step by step while checking the detection signal of the error microphone EM and measuring the difference between the highest level frequency components. It is a structure that goes and obtains a silencing effect. That is, when an error microphone EM detects a low-level frequency component in which the muffling effect is not recognized, and there is a difference of a certain level or more from the highest-level frequency component by the detection signal of the source microphone SM, an equalizer is used. Amplify and a little amplify, check the detection result of the error microphone EM, and if it is confirmed that the noise reduction effect is still not obtained, repeat the work of further amplification, the excessive amplification It avoids and approaches the optimal silence state.
[0025]
  The above has described the configuration in which the noise reduction effect is enhanced by providing the sound adjuster 3 or by providing an equalizer function effective to mute low-level frequency components in noise that could not be silenced conventionally. Next, in FIG. 5 and FIG. 6, the installation state of the speaker is improved, and the effective amplitude is drawn out to the maximum, thereby improving the level of the sound for silencing so that high level noise can be effectively silenced. A configuration to be described will be described. As shown in FIG. 5, the speaker S is built in a speaker box 5 that is a box for protection, and the front cone portion of the speaker S meets the branch pipe 4 (joins the sound wave interference section 2 of the main pipe 1). Not. In this state, since the static pressure in the branch pipe 4 is higher than the static pressure in the speaker box 5, the cone portion of the speaker S is pushed into the speaker box 5 side, that is, the rear side. The amplitude of the speaker S is a value obtained by subtracting the displacement due to the static pressure from the original maximum amplitude, and it is impossible to use the speaker S up to the original maximum sound pressure. Therefore, when the maximum sound pressure is generated, the distortion component in the speaker sound increases.
[0026]
  In order to correct this, it is effective to increase the internal pressure in the speaker box 5 to the same pressure as the static pressure in the branch pipe 4. Therefore, as shown in FIG. 5, a communication pipe 6 is provided for communicating between the inside of the branch pipe 4 and the inside of the speaker box 5 via the speaker S, and water, oil, etc. are provided in the communication pipe 6. Keep the liquid inside. In the communication pipe 6, the liquid is pushed from both sides by the air from the inside of the branch pipe 4 and the air from the inside of the speaker box 5, but since the air pressure from the inside of the branch pipe 4 is higher, the liquid is the speaker box 5. Pushed to the side. Therefore, the air on the speaker box 5 side is compressed from the liquid in the communication pipe 6, and this air enters the speaker box 5 and increases the internal pressure of the speaker box 5. Thus, the front side and the rear side of the speaker S have equal pressure, and the cone portion is returned to the initial shape, that is, the shape that is not pushed in, so that an effective amplitude corresponding to the voltage can be obtained.
[0027]
  Further, in the embodiment of FIG. 6, the speaker box 5 is built in the cooling box 7 in order to prevent the temperature of the speaker S from becoming high, and cooling air is supplied to the outside of the speaker box 5 in the cooling box 7. A fan 8 is provided for the purpose. A cooling duct 7a is formed between the outside of the speaker box 5 and the inside of the cooling box 7 of the cooling air from the fan 8, and the cooling air passing therethrough is branched from the front of the speaker S. 4 to flow in. In such a configuration, the speaker box 5 is provided with a static pressure correcting hole 5a communicating with a part of the cooling duct 7a. Since the high-pressure cooling air flows in the cooling duct 7a, a part of the cooling air enters the static pressure correcting hole 5a to increase the internal pressure in the speaker box 5. Further, since the cooling duct 7a communicates with the branch pipe 4, the air inside the cooling duct 7a is not introduced, so that the pressure inside the speaker box 5 is not excessively increased. Thus, the static pressure in the speaker box 5 becomes equal to the static pressure in the branch pipe 4, and the shape of the speaker S returns to the initial shape, and the set amplitude can be obtained.
[0028]
  Next, the configuration of an active silencer that can increase the silencing effect in response to changes in the state of the noise source will be described with reference to FIGS. (The configuration of the active silencer to be applied is the same as the configuration shown in FIGS. 1 to 4.) In this active silencer, the noise source is an internal combustion engine such as a ship. 1 is integral with the exhaust pipe. In this case, the internal combustion engine of the noise source has a constant torque at a constant rotational speed and a transient state such as when the engine speed changes (that is, the volume of the exhaust sound changes), such as when the engine is started or stopped, or when shifting. It is largely classified into a steady operation state in which the engine is operated (that is, the exhaust sound is stable at a constant volume).
[0029]
  On the other hand, in the controller, in order to obtain the output level to the loudspeaker that has the highest silencing effect, the output level is increased or decreased while ticking at a constant value so that the detection signal level of the error microphone EM approaches the minimum value. To control. The step value of the output level in this controller is called a convergence coefficient μ.
[0030]
  Among these, in a transient state, the convergence coefficient μ is set small in order to closely check the silencing effect and maintain control stabilization. If this is taken large, the error from the optimum output level becomes large, and the detection level of the error microphone EM becomes higher than the minimum value β to be set. (This is called the divergent state.) However, when the steady operation is started with the convergence coefficient μ kept small in this way, it takes time from the start of silencing until the final silencing effect is obtained. End up. Therefore, in this case, it is desirable to increase the convergence coefficient μ. FIG. 7 shows a comparison of the relationship between the magnitude of the convergence coefficient μ and the silence level in the transient state and the steady state. In the transient state, it can be seen that the smaller the convergence coefficient μ is, the larger the silencing volume is, i.e., the higher the silencing effect is.In steady state, the larger the convergence coefficient μ is, the larger the silencing volume is, and the silencing effect is enhanced. , Convergence coefficient μ in steady state₀ In the transient state, the convergence coefficient μ₁ (Μ₁ <Μ₀ ) To obtain the maximum volume level.
[0031]
  Therefore, in the controller, the convergence coefficient μ in the steady state₀ And convergence coefficient μ in the transient state₁ And determine whether the noise source is in a transient state or a steady state, and the convergence coefficient μ₀ ・ Μ₁ One of these is selected, and the output of the controller is controlled. As the determination of the transient state or the steady state, the amount of change in the noise detection level detected by the source microphone SM is detected. That is, in the silencing control procedure as shown in FIG. 8, if the amount of change in the detection level (SML) of the source microphone SM is smaller than the reference value d, it is determined as a steady state, and the convergence coefficient μ₀ If the amount of change is larger than the reference value d, it is determined that the transition state is present, and the convergence coefficient μ₁ And the volume control of the speaker S is performed.
[0032]
  Next, a means for finding a control unstable state due to a calculation error or the like of the controller will be described with reference to FIGS. In the active silencer, when the speaker sound becomes unstable in control, the silencing effect is reduced and the sound increase is generated. Eventually, it leads to the sound divergence state accompanied by abnormal noise. Possible causes include an increase in controller calculation error and the influence of external disturbances, but in any case, detecting this increase in the earliest stage before falling into the worst state that significantly attenuates the silencing effect It is a measure to return to the optimal state.
[0033]
  9 and FIG. 10 and FIG. 11 both compare the detection signal of the source microphone SM and the detection signal of the error microphone EM. In the case of FIG. A band-pass filter BF is provided in each of the sound input portions of the error microphone EM so that only sound of a specific frequency component is passed from the sound monitored by each microphone SM / EM. That is, only frequency components that are likely to be distorted are extracted particularly when control is unstable, and the sound increase is discriminated. The sound that has passed through the band-pass filter is converted into an electrical signal by a detector in the controller, and further, the signal from the error microphone EM, which is a sound signal after mute, is amplified by the muffled sound volume through an amplifier. In this way, the detection signal levels from the source microphone SM and the error microphone EM are set to a · b, and both levels are compared. If there is a silencing effect, it should be a = b (or a> b). If there is no silencing effect, the sound from the error microphone EM that is not muted is amplified by the amplifier. It should be <b. Thus, if it is recognized that there is no noise reduction effect, a stop signal for the apparatus is issued with the sound increased.
[0034]
  Note that it is a component on the high frequency side that has a short wavelength and is difficult to control that tends to be in a sound-increasing state. Assuming this, the band pass filter (for both microphones SM and EM) shown in FIG. 9 may be set to pass only high frequency components. That is, only high frequency components are extracted from the detection signals of the source microphone SM and the error microphone EM and compared, and if an increase in sound is recognized at this part in the error microphone EM, an alarm such as a stop signal is issued. The worker recognizes this warning and returns from the sound increase state.
[0035]
  The configurations shown in FIG. 10 and FIG. 11 detect the sound increase by comparing both the source microphone SM and the error microphone EM, but pass through the main pipe 1 in order to further improve the detection accuracy. The detection signal level of the source microphone SM is corrected in consideration of the propagation state of the sound wave to be transmitted. First, as shown in FIG. 10, the detection signal of the source microphone SM represents the sound state at the position where the source microphone SM is arranged, but the distance H to reach the sound wave interference unit 2.₀ During this time, the volume is attenuated. Control of speaker sound in the controller must be performed in anticipation of this attenuation. In order to input the detection signal from the error microphone EM to see the silencing effect, the distance H from the sound wave interference unit 2 to the error microphone EM₁ The amount of sound attenuation during the period must be taken into account. That is, the detection signal from the source microphone SM is a distance H from the source microphone SM to the sound wave interference unit 2.₀ Furthermore, the distance H from the sound wave interference unit 2 to the error microphone EM₁ If the sound attenuation during propagation of the sound is taken into consideration and compared with the detection signal of the error microphone EM, the correct silencing effect cannot be confirmed.
[0036]
  A constant functional expression is applied to the sound attenuation. Although this is called a transfer function, this transfer function varies depending on the state of the noise source, that is, when the exhaust gas of the internal combustion engine is used as the noise source. Therefore, a transfer function from the source microphone SM to the error microphone EM is obtained in a state where the engine is not operated, and this is corrected by a change in the operating state. From FIG. 11, the sound increase detection procedure in the present embodiment will be described. First, a signal is detected from the source microphone SM, and at the same time, the operating state of the engine is confirmed, a transfer function is set, and The detection signal level of the source microphone SM is substituted. Thus, the controller output signal C0 for obtaining the sound signal level of the muffled noise at the time of reaching the error microphone EM is estimated. On the other hand, the actual controller output signal C1 is detected. If the signal level C1 is higher than the estimated level C0 (C0 <C1), it means that the sound is not sufficiently muted, that is, the sound is in an increased state, and a warning signal is issued to give an alarm. If the same comparison is performed using the input signal to the speaker S instead of the controller output, the sound increase state can be detected even if the amplification factor of the amplifier driving the speaker S changes. .
[0037]
  Further, using the same transfer function, the signal level of the error microphone EM when the sound is not muted (speaker sound is not generated) is estimated from the detection signal of the source microphone SM, and compared with the actual detection signal level of the error microphone EM. If the actual value of the signal level is larger than the estimated value, it can be easily detected that the sound is increased more than the actual exhaust sound when the sound is not muted, and a warning is possible.
[0038]
  If the sound increase is determined by these determination methods, the control state, the speaker, etc. are immediately checked, and the return to stable mute is performed, thereby preventing the worst control failure. . If the cause of the increase in sound is due to an increase in calculation error in the controller, it is possible to return to the mute state by clearing the coefficient in the controller.In the case of a failure, the increase in high-frequency distortion due to deterioration of the speaker, etc. The cause is that it cannot be restored without replacing the speakers. The worst cause of sound increase is a speaker failure, and the above sound increase determination method may be used as it is as one of the subsequent methods for checking a speaker failure.
[0039]
  Next, a means for detecting a speaker failure will be described with reference to FIGS. That is, it is a means for detecting a speaker failure itself by taking a step further from the sound increase detection shown in FIGS. These are roughly classified into a type that detects a change in the state of the speaker itself and a type that detects a mute control state and determines that the speaker is faulty.
[0040]
  First, FIGS. 12 to 14 will be described as a type for detecting a change in the state of the speaker itself. As shown in FIG. 12, a humidity sensor is provided in the speaker box 5 covering the rear part of the speaker S. The cone portion on the front surface of the speaker S directly faces the branch pipe 4, but when the noise source is exhaust of the internal combustion engine, the branch pipe 4 contains a large amount of moisture in the exhaust. On the other hand, since the inside of the speaker box 5 is hermetically sealed, if the humidity is kept low during installation, the humidity should be low if normal. However, when a hole or a tear occurs in the cone of the speaker S that separates the inside of the branch pipe 4 from the inside of the speaker box 5, through this, moist air in the branch pipe 4 enters the speaker box 5, As shown in FIG. 13, the humidity detected by the humidity sensor increases. Therefore, as shown in FIG. 14, when the humidity reference value H0 in the speaker box 5 is set and the humidity detection value H1 of the humidity sensor becomes larger than the humidity reference value H0, it is determined that the speaker S is damaged, and a warning is given. It emits.
[0041]
  As another embodiment based on the detection of humidity, the one shown in FIGS. 15 to 17 will be described. As shown in FIG. 15, humidity sensors are arranged in the branch pipe 4 on the front side and the speaker box 5 on the rear side of the speaker S, respectively. The front side of the speaker S, that is, the detected humidity in the branch pipe 4 is H0, the detected humidity in the speaker box 5 is H1, and the humidity rise in the speaker box 5 is detected from the relationship between both detected humidity to determine the failure of the speaker. That is, as shown in FIGS. 16 and 17, the reference value of the difference between the humidity H1 in the speaker box 5 and the humidity in the branch pipe 4 is α (> 0), and H1> H0−α, that is, H1 + α> H0. If the humidity in the speaker box 5 is too high, it is determined that the speaker S is out of order and a warning is issued.
[0042]
  Next, means for indirectly determining a speaker failure by detecting the mute control state will be described with reference to FIGS. First, the means shown in FIGS. 18 and 19 are determined based on an input signal from the error microphone EM. This is the same concept as the determination method shown in FIG. That is, the means of FIG. 9 used as the sound increase determination method is applied as a speaker failure determination method in substantially the same manner. First, as shown in FIGS. 18A to 18B, a component having a frequency higher than the frequency to be muffled is extracted (with a bandpass filter or the like) from each frequency component detected by the error microphone EM. For the high frequency component, when the speaker is functioning normally in the controller as shown in FIG. 18C, the mute effect is applied to the sound after mute according to the output level (additional voltage to the speaker). The level range that is recognized as having been set. Note that the level range is also set stepwise in accordance with the state of the noise source (when the exhaust gas from the internal combustion engine is used as the noise source, the operating condition). The maximum value of this level region is set as a threshold value (reference value H0).
[0043]
  In this way, although the output level of the speaker is controlled so that it falls within the level range in the controller, as shown in FIG. 19, the object to be extracted from the actual sound after mute detected by the error microphone EM When the sound pressure level H1 of the high frequency component becomes higher than this threshold value (reference value H0), the silencing effect is not increased or the sound is increased in the high frequency component. Is determined to be caused by the failure (deterioration) of the speaker, and an alarm is issued.
[0044]
  20 and 21 determine the failure of the speaker based on the detection of the output level for the speaker output in the controller. When the speaker is functioning normally, the controller is set to the output level range where the silencing effect is most enhanced depending on the state of the noise source. If the noise source is the exhaust of the internal combustion engine, an output level range (a level range below the reference value shown in FIG. 20) is set in accordance with various operating conditions of the internal combustion engine. In this case, if the speaker is faulty, the output level is higher than the set reference value (maximum limit value in the set output level range) to increase the same noise reduction effect under certain operating conditions. I have to do it. This is because, when a failure such as deterioration occurs in the speaker, it is necessary to apply a voltage higher than that in the normal state in order to generate the same sound volume. In the controller, the output level is automatically adjusted so as to enhance the silencing effect on the basis of the detection signal of the error microphone EM, so that a certain silencing effect is enhanced, although there is a price for the output level.
[0045]
  With such a configuration, as shown in FIG. 21, a reference value C0 that is the maximum value of the normal output level range is set, and the output level at the controller is monitored, and how much output level is required to increase a certain silencing effect. It is detected whether C1 is required, and when the output level C1 is higher than the reference value C0, it is determined that the speaker is faulty and an alarm is issued. In the setting of the reference value C0, as described above, various reference values are set for each engine operating condition (for example, the rotational speed, exhaust temperature, load, etc.), and based on the engine operating condition at that time. In this case, one reference value C0 is selected. This is the same as the reference value C selection method in the flowchart of FIG. 26 based on the speaker failure determination method shown in FIG.
[0046]
  Comparing the determination means shown in FIGS. 18 and 19 with the determination means shown in FIGS. 20 and 21, the former determines a failure by detecting a part where the noise reduction effect does not increase, whereas the latter indicates the noise reduction effect. However, the failure is determined by detecting how much output is required to increase the normal silencing effect.
[0047]
  FIG. 22 shows a speaker when the method of extracting a high frequency component from the monitor signal of the error microphone EM shown in FIGS. 18 and 19 and the method of detecting the output level of the controller shown in FIGS. 20 and 21 are combined. The failure judgment method is shown. That is, the reference value H0 (threshold value) of the high frequency component extracted from the detection signal of the error microphone EM and the reference value C0 of the output level are set (set based on operating conditions). The output level H1 is detected by extracting the high frequency component that is the target of sound increase determination from the detection signal of the error microphone EM. If the output level H1 exceeds the reference value H0, the controller output C1 is further detected. When the reference value C0 is reached, an alarm is issued. Thus, the accuracy of the speaker failure determination is improved by combining the two determination means.
[0048]
  Next, FIG. 23 to FIG. 26 detect the state of displacement of the cone paper of the speaker S, and determine the failure of the speaker based on this detection and the detection of the output level for the speaker S in the controller. In other words, detection is performed by mixing detection of the speaker state itself and detection of the control state. In the detection method using the humidity sensor shown in FIGS. 12 and 15, the cone paper cannot be detected unless the front and back of the speaker S are in communication with each other, for example, a hole is formed in the cone paper. If the front and back of the speaker S are isolated from each other only by making them softer or softened, it is not determined that there is a failure, but in FIGS. 23 to 26 of this embodiment, the state of the cone paper itself is detected. In such a case, it can be determined that there is a failure.
[0049]
  First, as shown in FIG. 23, a displacement measuring means for measuring the change (displacement) of the cone paper of the speaker S is disposed in the rear part of the speaker S (rear part of the cone paper), that is, in the speaker box 5. The displacement amount of the cone paper is the amplitude of the cone paper at the time of vibration, that is, corresponds to the volume of the speaker sound. This detection signal is input to the controller. As shown in FIG. 24, the controller outputs an output level (voltage applied to the speaker S) corresponding to the displacement of the cone paper when the speaker S is functioning normally. Is stored as a reference value.
[0050]
  Thus, in the controller, as shown in FIG. 25, the output level reference value D set under the same operating conditions based on the signal relating to the displacement amount of the cone paper input from the displacement measuring means.₀ Is picked up and this is the actual output level D₁ Compare with If the cone paper of the speaker S is deteriorated, a large output level is required to displace (vibrate) the cone paper to the same amount (amplitude) as compared with the normal state. (Conversely, even if the same level of voltage is applied, if the cone paper is deteriorated, the amount of displacement becomes small.) Therefore, D₁ > D₀ Is recognized, it is determined that the cone paper of the speaker S has deteriorated, and an alarm is issued.
[0051]
  Further, as shown in FIG. 26, the reference value of the output level in this case also depends on the operating conditions (for example, the rotational speed, the exhaust temperature, the load, etc.) when the state of the noise source, that is, when the internal combustion engine exhaust is used as the noise source. Set in stages (C₁ ~ C_n ). Among these, the reference value C is determined based on the displacement detection by the displacement measuring means at that time and the operating conditions. If the actual output level D is higher than the actual output level D, an alarm is issued. I am doing so.
[0052]
【The invention's effect】
  Since the present invention is configured as described above, the following effects are achieved in the active silencer.
  First, by configuring as in claim 1, it is possible to amplify a low-level frequency component in noise that could not be silenced by an equalizer so that a sound that cancels this out can be generated from the speaker. It becomes possible to mute.
  That is, a low-level frequency component in which a muffling effect is not recognized is detected by the muffler detection unit, and if it has a certain level of difference from the highest-level frequency component by the detection signal of the noise detection unit, an equalizer is used. Amplify and a little amplify, check the detection result of the mute detection unit, and if it is confirmed that the mute effect is still not obtained, repeat the work of further amplification, the excess amplification It avoids and approaches the optimal silence state.
[0053]
  next,Claim 2With such a configuration, when the noise source exhibits a transient state in which the noise level increases or decreases and a steady state in which a certain level of noise is generated, it is possible to obtain an optimum silencing effect according to each state.
[0054]
  next,Claims 3 and 4By configuring as described above, it is possible to quickly detect an increase in sound that occurs due to instability of the control, which is caused by a speaker failure or an increase in calculation error of the controller, etc., before becoming the worst state where control is lost It is possible to stop the active silencer and start the inspection of each part and return to the normal silence state.
[Brief description of the drawings]
FIG. 1 is a schematic view of an active silencer having a sound adjuster 3 and a state of level correction.
FIG. 2 is a schematic diagram of an active silencer in which an equalizer is provided in a source microphone SM, and a diagram illustrating a state of level correction by the equalizer.
FIG. 3 is a schematic diagram of the active silencer and a diagram showing a state of level correction by an equalizer in consideration of a difference between a highest frequency component in a detection signal of the source microphone SM and a frequency component that cannot be silenced.
FIG. 4 is a diagram showing a state of level correction by an active silencer and a stepped equalizer as in the schematic diagram.
FIG. 5 is a diagram illustrating a state in which displacement of the speaker S is corrected by connecting the front and rear through a communication pipe 5;
FIG. 6 is a diagram illustrating a state in which the speaker box 5 and the cooling box 7 are communicated to correct the speaker S.
FIG. 7 is a graph showing a relationship between the silence level and the convergence coefficient at the time of engine transition and at the time of steady state.
FIG. 8 is a speaker sound control flowchart of the active silencer based on the selection of a convergence coefficient based on a determination between a transient time and a steady time.
FIG. 9 is a diagram showing a sound increase detection method by extracting and comparing a specific frequency component from detection signals of a source microphone SM and an error microphone EM.
FIG. 10 is a diagram showing a sound increase detection method by estimating the attenuation state of the source microphone SM detection signal level from the distance and the driving state and comparing it with the detection signal level of the error microphone EM.
11 is a flowchart of sound increase detection by the method of FIG.
FIG. 12 is a diagram showing a speaker failure detection method by providing a humidity sensor at the rear of the speaker.
13 is a graph showing a criterion for detecting a speaker failure in the method of FIG.
14 is a flowchart of speaker failure detection according to the method of FIGS. 12 and 13. FIG.
FIG. 15 is a diagram showing a speaker failure detection method by providing humidity sensors before and after the speaker.
16 is a graph showing a criterion for detecting a speaker failure in the method of FIG.
17 is a flowchart of speaker failure detection according to the method of FIGS. 15 and 16. FIG.
FIG. 18 is a diagram illustrating a speaker failure detection method by extracting a high frequency component from a detection signal of the error microphone EM and comparing it with a reference value.
19 is a flowchart of speaker failure detection by the method of FIG.
FIG. 20 is a graph showing a speaker failure detection criterion in a speaker failure detection method based on a comparison between a controller output and its reference value.
FIG. 21 is a flowchart of speaker failure detection based on detection of a controller output based on the detection criterion shown in FIG. 20;
22 is a speaker failure detection flowchart showing a combination of the method of FIGS. 18 and 19 and the method of FIGS. 20 and 21. FIG.
FIG. 23 is a diagram showing a speaker failure detection method by providing speaker displacement measuring means.
24 is a graph showing a criterion for detecting a speaker failure in the method of FIG. 23. FIG.
25 is a flowchart of speaker failure detection according to the method of FIGS. 23 and 24. FIG.
FIG. 26 is a speaker failure detection flowchart similarly including a process of determining a set reference value from operating conditions.
[Explanation of symbols]
  S Speaker
  SM source microphone
  EM error microphone
  1 Main
  2 Sound wave interference part
  3 tuner
  4 branch pipes
  5 Speaker box

Claims (4)

An active silencer that captures noise waves, generates sound waves in the opposite phase from the speakers, and merges them with the noise waves to mute the noise. A mute detection unit that detects the sound of the sound and converts it to an electrical signal, and inputs the detection signals of both detection units to the speaker voltage controller.
Among the frequency components in the detection signal of the noise detection unit, there is provided an equalizer mechanism that amplifies a component that does not reach a certain level to a certain level, and when a frequency component having no silencing effect is recognized by the detection signal of the silencing detection unit An active silencer characterized in that a difference with a maximum level frequency component is calculated, and when this exceeds a set reference difference, amplification adjustment is performed by the equalizer function. The active silencer according to claim 1,
When the noise source exhibits a transient state in which the noise level increases or decreases and a steady state in which a certain level of noise is generated, a coefficient for converging the speaker control output level of the controller to the optimum value is used for the transient state. An active silencer, wherein the coefficient is selected by determining whether the state is a transient state or a steady state based on the rate of change in the detection level of the noise detection unit. The active silencer according to claim 1,
The noise detection unit and the mute detection unit are provided with means for extracting a specific frequency component, and a sound increase occurring due to control instability is detected by comparing the level of the frequency component extracted from both detection units. An active silencer characterized by that. The active silencer according to claim 1,
The detection signal level of the noise detection unit is substituted into a level attenuation function set based on the distance to the mute detection unit position and the state of the noise source, and this value is compared with the detection signal level of the mute detection unit. Thus, an active silencer is provided that detects an increase in sound that occurs due to unstable control.

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