JP2012032119A - Air conditioner - Google Patents

Abstract

PROBLEM TO BE SOLVED: To provide an air conditioner that can reduce costs by making the number of parts for a silencing mechanism small and achieve a constant noise reduction effect without deteriorating aerodynamic performance.SOLUTION: The air conditioner 1 includes: a housing having a suction port 3 and a discharge port 5 formed therein; air blowing fans 21-23 provided in the housing; a heat exchanger 4 disposed in the housing; noise detecting microphones 61, 62 for detecting noise from the air blowing fans 21-23; control speakers 81, 82 for outputting a control sound for reducing the noise; silencing effect detection microphones 91, 92 for detecting the silencing effect by the control sound; signal processor devices 101, 102 for outputting the control sound from the control speakers 81, 82 based on the detected results by the noise detecting microphones 61, 62 and the silencing effect detection microphones 91, 92; and a controller 6 for performing a rotation control to each of the air blowing fans 21-23.

Description

  The present invention relates to an air conditioner equipped with a silencer mechanism for reducing noise such as a blower fan.

  In order to reduce the noise represented by the driving sound of the blower fan, passive noise reduction methods such as sound absorption and sound insulation have been conventionally performed. However, these methods are known to be effective in reducing noise in a relatively high frequency band, but are ineffective in low frequency band noise such as driving sound of a blower fan.

  As an improvement measure, an active noise reduction method is used in which noise is reduced by outputting a control sound having the same amplitude and opposite phase with respect to noise from a speaker or the like and causing interference with the noise. The mute mechanism used for such an active mute method generally includes a sound receiver (such as a sensing microphone), a signal processing device configured by a digital filter and an adaptive algorithm, and a sound generator (such as a control speaker). And an error signal detection sensor (evaluation microphone or the like). Then, a sound receiver is arranged on the downstream side of the sound source to detect sound generated from the sound source, and a control signal having the same amplitude and opposite phase as the noise is created based on the detected sound. The control signal created by the signal processing device is input to the sound generator and output as a control sound. Further, the control result of active silencing is evaluated by the error signal detection sensor arranged at the control point to be silenced, and the filter coefficient of the digital filter of the signal processing device is set so that the error signal detected by the error signal detection sensor is minimized. Update.

  A conventional air conditioner to which such an active silencing method is applied is disclosed in Patent Document 1, for example. The air conditioner described in Patent Document 1 arranges one microphone for detecting noise at the center in the longitudinal direction of an air passage (hereinafter referred to as an air passage) against noise radiated from a line flow fan, Two sound generators are arranged at both ends in the longitudinal direction of the air flow path, and two error signal detection sensors are arranged downstream of the sound generator (both ends in the longitudinal direction of the air flow path) to reduce noise. Yes.

  Here, the magnitude of noise generated from a single line flow fan is uniform over the entire outlet area. On the other hand, in the active silencing method, the control works so as to reduce the noise detected by the error signal detection sensor serving as a control point. For this reason, noise in the vicinity of the error signal detection sensor is reduced, but the noise reduction effect is reduced at a point away from the error signal detection sensor. This is because the phase of the control sound radiated from the sound generator changes at a point away from the error signal detection sensor. That is, when the active silencing method is applied to a noise source having a uniform amount of noise radiated into the room, such as a single line flow fan, there is a region where the silencing effect cannot be obtained. Therefore, the sound radiated from the region where the silencing effect cannot be obtained feels annoying, and as a result, the silencing effect of the entire air conditioner is reduced.

  In order to solve the problem of the above active silencing method, for example, “the monopole sound source 3 is inserted in the longitudinal direction of the cross flow fan 2 of the air conditioner 1 and the flow blown from the cross flow fan 2 is sandwiched. Thus, a plurality of such arrangements are proposed at intervals shorter than a quarter wavelength of the sound corresponding to the upper limit value of the noise control frequency band (see, for example, Patent Document 2).

JP-A-4-281125 (paragraph 0022, FIG. 2) JP 2005-37447 A (summary, FIG. 1)

  In the air conditioner described in Patent Document 2, it is necessary to arrange a plurality of speakers and microphones (monopole sound sources) at intervals shorter than a quarter wavelength of the sound corresponding to the upper limit value of the noise control frequency band. For example, when the length of the air conditioner in the longitudinal direction (more specifically, the longitudinal direction of the air flow path) is 72 cm and the upper limit of the noise control frequency band is 1 kHz, 1/4 of the wavelength is about 8 cm. There are nine installation locations. Furthermore, in order to arrange the speakers and microphones so as to sandwich the flow blown out from the cross flow blower, 18 speakers and microphones that are twice the installation location are required. Therefore, the air conditioner described in Patent Document 2 has a problem that the number of parts of the silencer mechanism increases at a stretch and the cost increases.

  Moreover, since the air conditioner described in Patent Document 2 is configured with an analog control circuit that generates control sound, it has a configuration that cannot perform control with higher accuracy than digital control. Furthermore, the air conditioner described in Patent Document 2 has a configuration that cannot follow changes in the environment, such as when the speed of sound changes due to the influence of a temperature change or the like. Therefore, the air conditioner described in Patent Document 2 has a problem that a high silencing effect cannot be obtained.

  The present invention has been made to solve at least one of such problems, and by reducing the number of parts of the silencing mechanism by the active silencing characteristics and the structure of the blower fan, the aerodynamic performance is reduced. It aims at providing the air conditioner which can acquire the fixed noise reduction effect, without deteriorating.

  An air conditioner according to the present invention includes a housing in which an inlet and an outlet are formed, an impeller, a plurality of blower fans provided in the housing, and a heat exchange provided in the housing. A noise detection device that detects noise radiated from the blower fan, a control sound output device that outputs a control sound that reduces the noise, and a silencing effect detection device that detects a silencing effect due to the control sound, Based on the detection results of the noise detection device and the silencing effect detection device, a control sound generation device that causes the control sound output device to output the control sound, and a control that individually controls the rotational speed for the plurality of blower fans And a device.

  In addition, the air conditioner according to the present invention includes a casing in which an inlet and an outlet are formed, an impeller, a plurality of blower fans provided in the casing, and the casing. A heat exchanger, a control sound output device that outputs a control sound that reduces noise radiated from the blower fan, and a noise / silence effect detection device that detects the noise and detects the silencing effect of the control sound; A control sound generation device that causes the control sound output device to output the control sound based on the detection result of the noise / silence effect detection device, and a control device that individually controls the rotational speed of the plurality of blowing fans. , With.

  In addition, the air conditioner according to the present invention includes a casing in which an inlet and an outlet are formed, an impeller, a plurality of blower fans provided in the casing, and the casing. A heat exchanger, a noise detection device that detects noise radiated from the blower fan, a control sound output device that outputs a control sound that reduces the noise, and a silencing effect detection device that detects a silencing effect due to the control sound And a control sound generation device that causes the control sound output device to output the control sound based on detection results of the noise detection device and the silencing effect detection device, and individually controls the rotational speed for the plurality of blower fans. And a control device that performs rotation speed control to increase the rotation speed of the blower fan disposed at both ends of the casing, and the control device other than the blower fan disposed at both ends of the casing. Rotation of the blower fan And performs at least one of the rotational speed control of the rotational speed control to lower the.

  In addition, the air conditioner according to the present invention includes a casing in which an inlet and an outlet are formed, an impeller, a plurality of blower fans provided in the casing, and the casing. A heat exchanger, a control sound output device that outputs a control sound that reduces noise radiated from the blower fan, and a noise / silence effect detection device that detects the noise and detects the silencing effect of the control sound; A control sound generation device that causes the control sound output device to output the control sound based on the detection result of the noise / silence effect detection device, and a control device that individually controls the rotational speed of the plurality of blowing fans. The control device includes a rotational speed control for increasing the rotational speed of the blower fan disposed at both ends of the casing, and the blower fan other than the blower fan disposed at both ends of the casing. Rotational speed to lower the rotational speed And it performs at least one of the rotational speed control of the control.

  The air conditioner according to the present invention includes a “noise reduction device including a noise detection device, a control sound output device, a noise reduction effect detection device, and a control sound generation device”, or “a control sound output device, a noise / noise reduction effect detection device, and A muffler mechanism including a control sound generator is provided. Furthermore, the air conditioner according to the present invention includes a plurality of blower fans and a control device that individually controls the rotational speed of the blower fans. For this reason, by controlling the rotation speed of each blower fan based on the silencing effect, there is no need to install a control sound output device or the like constituting the silencing mechanism for every quarter wavelength of the control target frequency. The number of parts can be reduced, and the cost of the air conditioner can be reduced. In addition, a certain noise reduction effect can be obtained without deteriorating the aerodynamic performance. In other words, the air conditioner according to the present invention can obtain a high silencing effect as compared with the air conditioner described in Patent Document 2 having the same number of silencing mechanisms.

It is a front view which shows the structure of the air conditioner which concerns on Embodiment 1,6 of this invention. It is a longitudinal cross-sectional schematic diagram which shows the structure of the air conditioner which concerns on Embodiment 1,6 of this invention. It is a block diagram which shows the silence mechanism which concerns on Embodiment 1,6 of this invention. It is a block diagram which shows the control apparatus which concerns on Embodiment 1,4,6,7 of this invention. It is a front view which shows another example of the air conditioner which concerns on Embodiment 1,6 of this invention. It is a left view of the air conditioner shown in FIG. It is a front view which shows the structure of the air conditioner which concerns on Embodiment 2 of this invention. It is a block diagram which shows the control apparatus which concerns on Embodiment 2 of this invention. It is a front view which shows another example of the air conditioner which concerns on Embodiment 2 of this invention. It is a left view of the air conditioner shown in FIG. It is a front view which shows another example of the air conditioner which concerns on Embodiment 2 of this invention. It is a front view which shows the structure of the air conditioner which concerns on Embodiment 3 of this invention. It is a block diagram which shows the control apparatus which concerns on Embodiment 3 of this invention. It is a front view which shows the structure of the air conditioner which concerns on Embodiment 4, 7 of this invention. It is a block diagram which shows the silencer mechanism which concerns on Embodiment 4,5,7 of this invention. It is a wave form diagram for demonstrating the method of calculating the noise which wants to mute from the sound after interference. It is a block diagram for demonstrating the method of estimating the control sound of Embodiment 4,5,7 of this invention. It is a front view which shows another example of the air conditioner which concerns on Embodiment 4, 7 of this invention. It is a left view of the air conditioner shown in FIG. It is a front view which shows the structure of the air conditioner which concerns on Embodiment 5 of this invention. It is a front view which shows another example of the air conditioner which concerns on Embodiment 5 of this invention. It is a left view of the air conditioner shown in FIG. It is a front view which shows another example of the air conditioner which concerns on Embodiment 5 of this invention. It is a front view which shows the structure of the air conditioner which concerns on Embodiment 8 of this invention. It is a block diagram which shows the control apparatus which concerns on Embodiment 8 of this invention. It is a block diagram which shows the silence volume calculation means which concerns on Embodiment 8 of this invention. It is a front view which shows the structure of the air conditioner which concerns on Embodiment 9 of this invention.

  Hereinafter, an example of an embodiment of an air conditioner according to the present invention will be described in detail with reference to the drawings.

<A. Embodiment 1>
<A-1. Configuration>
FIG. 1 is a front view showing a configuration of an air conditioner according to Embodiment 1 of the present invention. FIG. 2 is a side view showing the configuration of the air conditioner shown in FIG. 2 is a view of the air conditioner 1 shown in FIG. 1 as seen from the direction of the shaded arrow in FIG. 1, and shows a side wall of the casing of the air conditioner 1 in a transparent manner. 2, illustration of the remote controller 7, the control device 6, and the motor drivers 51 to 53 shown in FIG. 1 is omitted.

  The air conditioner 1 shown in FIG.1 and FIG.2 comprises an indoor unit, and the inlet 3 is formed in the upper part of the air conditioner 1 (more specifically, the housing | casing of the air conditioner 1), and air An outlet 5 is formed at the lower end of the conditioner 1 (more specifically, the casing of the air conditioner 1). That is, in the air conditioner 1, an air flow path that connects the suction port 3 and the blowout port 5 is formed. A plurality of blower fans having an impeller are provided along the left-right direction (longitudinal direction) below the suction port 3 in the air flow path. In the first embodiment, for example, three blower fans (blower fans 21 to 23) which are axial fans are provided. These blower fans 21 to 23 are provided such that the center of rotation of the impeller is in a substantially vertical direction. Each of these blower fans 21-23 is connected to the blower fan control means 71 of the control apparatus 6 via the motor drivers 51-53. Details of the control device 6 will be described later.

  Below the blower fans 21 to 23, a heat exchanger 4 is disposed that heat-exchanges air to cool or heat it. As shown by the white arrows in FIG. 1, when the blower fans 21 to 23 are activated, the indoor air is sucked into the air flow path in the air conditioner 1 from the suction port 3, and this intake air is sent to the blower fans 21 to 23. After cooling or heating with the heat exchanger 4 in the lower part, the air is blown out into the room through the outlet 5.

  Further, the air conditioner 1 according to the first embodiment is provided with a silencer mechanism used for active silence. The silencing mechanism of the air conditioner 1 according to the first embodiment includes noise detection microphones 61 and 62, control speakers 81 and 82, silencing effect detection microphones 91 and 92, and signal processing devices 101 and 102. That is, the silencing mechanism of the air conditioner 1 according to Embodiment 1 includes two noise detection microphones, two control speakers, and two silencing effect detection microphones. Hereinafter, the silencer mechanism composed of the noise detection microphone 61, the control speaker 81, the silencer detection microphone 91, and the signal processing device 101 is referred to as a silencer A. Further, a silencing mechanism including the noise detection microphone 62, the control speaker 82, the silencing effect detection microphone 92, and the signal processing device 102 is referred to as a silencing mechanism B.

  The noise detection microphones 61 and 62 are noise detection devices that detect the operation sound (noise) of the air conditioner 1 including the blowing sound of the blower fans 21 to 23 (noise emitted from the blower fans 21 to 23). The noise detection microphones 61 and 62 are provided at positions downstream of the blower fans 21 to 23 (for example, between the blower fans 21 to 23 and the heat exchanger 4). The noise detection microphone 61 is provided on the left side surface of the air conditioner 1, and the noise detection microphone 62 is provided on the right side surface of the air conditioner 1.

  The control speakers 81 and 82 are control sound output devices that output a control sound for noise. The control speakers 81 and 82 are provided at positions downstream of the noise detection microphones 61 and 62 (for example, downstream of the heat exchanger 4). The control speaker 81 is provided on the left side surface of the air conditioner 1, and the control speaker 82 is provided on the right side surface of the air conditioner 1. And the control speakers 81 and 82 are arrange | positioned so that it may face the center of an air flow path from the wall surface of the housing | casing of the air conditioner 1. FIG.

  The silencing effect detection microphones 91 and 92 are silencing effect detection devices that detect the silencing effect by the control sound. The mute effect detection microphones 91 and 92 are provided at positions downstream of the control speakers 81 and 82. Further, the silencing effect detection microphone 91 is provided, for example, substantially on the extension line of the rotation axis of the blower fan 21, and the silencing effect detection microphone 92 is provided, for example, on the extension line of the rotation axis of the blowing fan 23. In the first embodiment, the silencing effect detection microphones 91 and 92 are provided on the casing of the blowout nozzle that forms the blowout port 5. That is, the silencing effect detection microphones 91 and 92 detect the noise coming out from the outlet 5 and detect the silencing effect.

  The signal processing device 101 causes the control speaker 81 to output a control sound based on the detection results of the noise detection microphone 61 and the silencing effect detection microphone 91. Output signals from the noise detection microphone 61 and the mute effect detection microphone 91 are input to the signal processing device 101, and the signal processing device 101 generates a signal for controlling the control speaker 81. The signal processing device 102 causes the control speaker 82 to output a control sound based on the detection results of the noise detection microphone 62 and the silencing effect detection microphone 92. Output signals from the noise detection microphone 62 and the mute effect detection microphone 92 are input to the signal processing device 102, and the signal processing device 102 generates a signal for controlling the control speaker 82.

  Note that the noise detection microphones 61 and 62, the control speakers 81 and 82, and the silencing effect detection microphones 91 and 92 are attached in order from the downstream side of the blower fans 21 to 23, and the noise detection microphones 61 and 62, the control speakers 81 and 82, and It is only necessary to install the mute effect detection microphones 91 and 92 in this order, and the present invention is not limited to the positions shown in FIGS.

  FIG. 3 is a configuration diagram showing the muffler mechanism according to Embodiment 1 of the present invention. In addition, in FIG. 3, the block diagram of the silencer A is shown. Since the silencing mechanism A and the silencing mechanism B have the same configuration, the configuration of the silencing mechanism A will be described below as a representative.

  The electric signal input from the noise detection microphone 61 is amplified by the microphone amplifier 11 in the signal processing apparatus 101 and converted from an analog signal to a digital signal by the A / D converter 12. The electric signal input from the muffling effect detection microphone 91 is amplified by the microphone amplifier 11 and converted from an analog signal to a digital signal by the A / D converter 12. Each digital signal converted in this way is input to the FIR filter 18 and the LMS algorithm 19. In the FIR filter 18, control is performed so that the noise detected by the noise detection microphone 61 has the same amplitude and opposite phase as the noise when it reaches the place (control point) where the muffling effect detection microphone 91 is installed. Generate a signal. This control signal is converted from a digital signal to an analog signal by the D / A converter 14, amplified by the amplifier 15, and emitted from the control speaker 81 as a control sound. The silencer mechanism B has the same configuration as this.

FIG. 4 is a configuration diagram illustrating the control device according to the first embodiment of the present invention.
Various operations and means described below are performed by executing a program incorporated in the control device 6 included in the air conditioner 1. The control device 6 mainly includes an input unit 30 for inputting a signal from an external input device such as the remote controller 7, a CPU 31 for performing an operation according to an incorporated program, and a memory 32 for storing data and programs. Further, the CPU 31 includes a blower fan control means 71.

  The blower fan control means 71 includes the same rotation speed determination means 33, a fan individual rotation speed determination means 34, and a plurality of SWs 35 (the same number as the blower fan). The rotation speed determination means 33 determines the rotation speed when all the blower fans 21 to 23 are operated at the same rotation speed based on the operation information input from the remote controller 7. The operation information input from the remote controller 7 is, for example, operation mode information such as a cooling operation mode, a heating operation mode, and a dehumidifying operation mode, and air volume information such as strong, medium, and weak. The fan individual rotation speed determination means 34 determines each rotation speed when individually controlling the rotation speeds of the blower fans 21 to 23. The SW 35 switches the rotation control signals of the blower fans 21 to 23 sent to the motor drivers 51 to 53 based on, for example, a signal input from the remote controller 7. That is, the SW 35 switches between operating all the blower fans 21 to 23 at the same rotational speed or operating the blower fans 21 to 23 at individual rotational speeds.

<A-2. Operation>
Next, the operation of the air conditioner 1 will be described.
When the air conditioner 1 operates, the impellers of the blower fans 21 to 23 rotate, the indoor air is sucked in from the upper side of the blower fans 21 to 23, and the air is sent to the lower side of the blower fans 21 to 23. Airflow is generated. Along with this, an operating sound (noise) is generated in the vicinity of the air outlets of the blower fans 21 to 23, and the sound propagates downstream. The air sent by the blower fans 21 to 23 passes through the air flow path and is sent to the heat exchanger 4. For example, in the case of cooling operation, low-temperature refrigerant is sent to the heat exchanger 4 from a pipe connected to an outdoor unit (not shown). The air sent to the heat exchanger 4 is cooled by the refrigerant flowing through the heat exchanger 4 to become cold air, and is directly discharged into the room from the outlet 5.

Next, a method for suppressing the operation sound of the air conditioner 1 will be described. Since the silencer A and the silencer B are the same operation, the operation of the silencer A will be described below as a representative.
The operation sound (noise) including the blowing sound of the blower fans 21 to 23 in the air conditioner 1 is detected by the noise detection microphone 61 attached downstream of the blower fan 21. The noise detected by the noise detection microphone 61 becomes a digital signal via the microphone amplifier 11 and the A / D converter 12 and is input to the FIR filter 18 and the LMS algorithm 19.

  The tap coefficient of the FIR filter 18 is sequentially updated by the LMS algorithm 19. In the LMS algorithm 19, the optimum tap coefficient is updated so that the error signal e approaches zero according to the equation 1 (h (n + 1) = h (n) + 2 · μ · e (n) · x (n)). .

  Here, h is a filter tap coefficient, e is an error signal, x is a filter input signal, and μ is a step size parameter. The step size parameter μ controls the filter coefficient update amount for each sampling.

  In this way, the digital signal having the tap coefficient updated by the LMS algorithm 19 and passing through the FIR filter 18 is converted into an analog signal by the D / A converter 14, amplified by the amplifier 15, and outputted as a control sound from the control speaker 81. It is discharged into the air flow path in the air conditioner 1.

  On the other hand, the muffler effect detection microphone 91 mounted on the substantially extended line of the rotating shaft of the blower fan 21 on the casing of the blowout nozzle forming the blowout port 5 of the air conditioner 1 is connected to the air flow path from the blower fans 21 to 23. The sound after the control sound emitted from the control speaker 81 interferes with the noise propagated through the sound is detected. The signal detected by the silencing effect detection microphone 91 is input to the signal processing device 101.

  The signal from the mute effect detection microphone 91 input to the signal processing apparatus 101 in this way is handled as the error signal e of the LMS algorithm 19 described above. Then, feedback control is performed so that the error signal e approaches zero, and the tap coefficient of the FIR filter 18 is appropriately updated. As a result, noise in the vicinity of the muffler effect detection microphone 91 can be suppressed by the control sound that has passed through the FIR filter 18.

  As described above, in the active silencing method, the control sound is output from the control speakers 81 and 82 so as to have an opposite phase to the noise at the installation location (control point) of the silencing effect detection microphones 91 and 92. For this reason, the silencing effect becomes high in the vicinity of the silencing effect detecting microphones 91 and 92, but the phase of the control sound changes as the distance from the point increases. Therefore, at a location away from the muffler effect detection microphones 91 and 92, the phase shift between the noise and the control sound is increased, and the muffler effect is reduced.

Next, a control method for individually controlling the rotational speeds of the blower fans 21 to 23 (hereinafter also referred to as fan individual control) will be described.
Operation information selected by the remote controller 7 is input to the control device 6. As described above, the operation information is, for example, operation mode information such as a cooling operation mode, a heating operation mode, and a dehumidifying operation mode. Further, the air volume information such as strong, medium, and weak is similarly input as operation information from the remote controller 7 to the control device 6. The operation information input to the control device 6 is input to the rotation speed determination means 33 via the input unit 30. The rotation speed determination means 33 to which the operation information is input determines the rotation speed when all the blower fans 21 to 23 are operated at the same rotation speed from the input operation information. When the individual fan control is not performed, all of the blower fans 21 to 23 are controlled at the same rotational speed (hereinafter also referred to as the same rotational speed control).

  Information on the rotational speed (the rotational speed at the same rotational speed control) determined by the rotational speed determination means 33 is input to the fan individual rotational speed determination means 34. On the other hand, the fan individual rotation speed determination means 34 reads out the blower fan information stored in the memory 32 in advance at the time of product shipment. This blower fan information is information on a blower fan that emits noise with a high silencing effect when the control sound interferes. That is, the blower fan information is information on the blower fan that is highly related to the muffler effect detection microphones 91 and 92. These identification numbers are assigned to each silencing effect detection microphone. In the first embodiment, as the blower fan information, the identification number of the blower fan that is closest (highly related) to the silencing effect detection microphones 91 and 92 is used. Specifically, the identification number of the blower fan 21 that is the closest to the silencing effect detection microphone 91 and the identification number of the blower fan 23 that is the closest to the silencing effect detection microphone 92.

  The fan individual rotation speed determination means 34 determines the rotation speed of each blower fan when performing individual fan control based on the rotation speed information determined by the rotation speed determination means 33 and the blower fan information read from the memory 32. . Specifically, the fan individual rotation speed determination means 34 increases the rotation speed of the blower fans 21 and 23 located closest to the silencing effect detection microphones 91 and 92 so that the distance from the silencing effect detection microphones 91 and 92 is increased. The rotational speed of the blower fan 22 is reduced. At this time, it is good to determine each rotation speed of the ventilation fans 21-23 so that the air volume obtained when individual fan control is performed becomes the same air volume as that at the same rotation speed control. Since the air volume and the rotational speed are in a proportional relationship, for example, in the case of the configuration shown in FIG. 1, when the rotational speed of the blower fan 21 and the blower fan 23 is increased by 10%, the rotational speed of the blower fan 22 is decreased by 20%. With the same air volume.

  When an operation information signal indicating that individual fan control is performed from the remote controller 7 (for example, a signal such as a silent mode), the rotation control signal for the same speed control is changed to the rotation control signal for the individual fan control by switching the SW 35. This rotation control signal is output from the control device 6 to the blower fans 21 to 23. The rotation control signal output from the control device 6 is input to the motor drivers 51 to 53, and the blower fans 21 to 23 are controlled to the number of rotations according to the rotation control signal.

  As described above, when active silencing is performed, the silencing effect detecting microphones 91 and 92 serving as control points for noise control and the surrounding silencing effects are enhanced, but the control speakers 81 and 82 are used at locations away from the control points. The phase shift between the radiated control sound and noise is increased, and the silencing effect is reduced. However, in this Embodiment 1, it is set as the structure provided with the several ventilation fans 21-23 in the air conditioner 1, and the ventilation fans 21 and 23 (distance close | similar to the silencing effect detection microphones 91 and 92 with a high silencing effect are near. It is possible to increase the rotation speed of a fan that radiates noise having a high silencing effect and to decrease the rotation speed of the blower fan 22 (fan that emits noise having a low silencing effect) that is far from the silencing effect detection microphones 91 and 92. it can.

  As a result, in the air conditioner 1 according to the first embodiment, the region where the silencing effect is high further increases the silencing effect, and the region where the silencing effect is low is low in noise. Therefore, the air conditioner using a single blower fan is used. The noise radiated from the entire outlet 5 can be reduced as compared with the air conditioner that does not perform the machine and fan individual control. In other words, the air conditioner 1 according to the first embodiment does not need to install the number of control speakers for each quarter wavelength of the control target frequency, and can reduce the number of control speakers, which is costly. In addition to being reduced, a certain noise reduction effect can be obtained. Further, the air conditioner 1 according to the first embodiment controls aerodynamic performance by individually controlling the rotational speeds of the plurality of blower fans 21 to 23 so that the air volume is constant when the rotational speed control is performed. Can be prevented.

  Furthermore, as shown in FIGS. 5 and 6, the silencing effect can be further improved by dividing the air flow path of the air conditioner 1 into a plurality of regions.

  FIG. 5 is a front view showing another example of the air conditioner according to Embodiment 1 of the present invention. FIG. 6 is a left side view of the air conditioner shown in FIG. FIG. 6 shows the side wall of the casing of the air conditioner 1 in a transparent manner. The air conditioner 1 shown in FIGS. 5 and 6 divides the air flow path with the partition member 54, thereby allowing the air blown by the blower fan 21 to pass therethrough, the region through which the blown fan 22 blows air, and the blower fan 23. Is divided into areas through which air blows out. The noise detecting microphone 61, the control speaker 81, and the silencing effect detecting microphone 91 of the silencing mechanism A are arranged in an area through which the air blown out by the blower fan 21 passes. In addition, the noise detection microphone 62, the control speaker 82, and the noise reduction effect detection microphone 92 of the silencer B are disposed in a region through which the air blown out by the blower fan 23 passes.

  By configuring the air conditioner 1 in this way, the noise radiated from the blower fans 21 to 23 can be separated into the respective regions, and the silencing mechanism A reduces only the noise radiated from the blower fan 21. The silencing mechanism B reduces only the noise radiated from the blower fan 23. For this reason, since it is possible to prevent the noise detection microphones 61 and 62 and the silencing effect detection microphones 91 and 92 from detecting the noise radiated from the blower fan 22, the noise detection microphones 61 and 62 and the silencing effect detection microphone 91, 92 crosstalk noise components are reduced.

  Furthermore, since the air flow path is close to the duct structure, noise can be captured in one dimension. For this reason, the phase of the noise transmitted through the air conditioner 1 becomes uniform, and the phase error when the control sound interferes is reduced, so that the silencing effect is further enhanced. On the other hand, by reducing the rotational speed of the blower fan 22 that is not provided with the silencing mechanism, the noise in the area where the silencing mechanism is not provided is reduced. Therefore, by configuring the air conditioner 1 as shown in FIGS. 5 and 6, noise can be further reduced as compared with the configuration of FIG. 1. That is, even if the air conditioner 1 is configured as shown in FIGS. 5 and 6, it is not necessary to install the number of control speakers for each quarter wavelength of the control target frequency, and the number of control speakers can be reduced. Therefore, the cost is reduced and a certain noise reduction effect can be obtained. 5 and 6, the partition member 54 is inserted in the entire air flow path. However, for example, only a part of the air flow path is arranged upstream of the heat exchanger 4 or only downstream of the heat exchanger 4. You may make it partition | separate with the partition member 54. FIG.

  In the first embodiment, the noise detection microphones 61 and 62 are installed on both sides of the air conditioner 1, but the noise detection microphones 61 and 62 may be installed anywhere as long as they are upstream of the control speakers 81 and 82. . Further, in the first embodiment, the control speakers 81 and 82 are arranged on both side surfaces of the air conditioner 1. However, the control speakers 81 and 82 are arranged on the downstream side of the noise detection microphones 61 and 62 and on the upstream side of the silencing effect detection microphones 91 and 92. For example, the installation positions of the control speakers 81 and 82 may be anywhere. Further, in the first embodiment, the silencing effect detection microphones 91 and 92 are arranged on substantially the extension lines of the rotation shafts of the blower fans 21 and 23, but the silencing effect detection microphone 91 is provided on the downstream side of the control speakers 81 and 82. 92 can be installed anywhere. Furthermore, in the first embodiment, two noise detection microphones, control speakers, muffler effect detection microphones, and signal processing devices are disposed, but the present invention is not limited to this.

  In the first embodiment, the blower fan control means 71 is configured by the CPU 31 in the control device 6, but the blower fan control means 71 is implemented by hardware such as LSI (Large Scale Integration) or FPGA (Field Programmable Gate Array). May be configured. Further, the configuration of the blower fan control means 71 is not limited to the configuration shown in FIG.

  Moreover, in this Embodiment 1, although the case of the axial flow fan was mentioned as an example as the several ventilation fans 21-23, it should just be a fan which blows by rotating an impeller, and a sirocco fan or a line flow Of course, you may use a fan as the ventilation fans 21-23. Moreover, the ventilation fans 21-23 do not need to be provided in the upstream of the heat exchanger 4, for example, may be provided in the downstream of a heat exchanger.

  In the first embodiment, the FIR filter 18 and the LMS algorithm 19 are used for the signal processing devices 101 and 102. However, any adaptive signal processing circuit that can reduce the sound detected by the mute effect detection microphones 91 and 92 to zero. It is also possible to use a filtered-X algorithm that is generally used in the active silencing method. Further, the signal processing devices 101 and 102 do not need to be configured to perform adaptive signal processing, and may be configured to generate control sound using a fixed tap coefficient. Further, the signal processing devices 101 and 102 do not have to be digital signal processing circuits, but may be analog signal processing circuits. In the first embodiment, the signal processing apparatuses 101 and 102 are configured as a 1-input 1-output system. However, the signal processing apparatuses 101 and 102 may be configured as a multi-input multi-output system.

  Further, in the first embodiment, the blower fan control means 71 increases the rotational speed of the blower fans 21 and 23 that are close to the muffler effect detection microphones 91 and 92 and the rotational speed of the blower fan 22 that is far away. Although it is configured to be lowered, it may be configured to perform either one of them.

<A-3. Effect>
As described above, in the air conditioner 1 according to Embodiment 1, a plurality of blower fans 21 to 23 are arranged, and the control device 6 that individually controls the rotational speed of the blower fans 21 to 23 (more specifically, the blower fan) Control means 71) are provided. The blower fan control means 71 performs control so as to increase the rotational speed of the blower fans 21 and 23 that blow air to the area in the vicinity of the silencing effect detection microphones 91 and 92, which is the area where the silencing effect is high, and the silencing effect is reduced. The rotational speed control is performed so as to reduce the rotational speed of the blower fan 22 that blows air to a region far from the muffler effect detection microphones 91 and 92 that are regions. For this reason, the region where the silencing effect is high has a higher silencing effect, and the region where the silencing effect is low has less noise. For this reason, compared with the air conditioner which uses a single ventilation fan with the silencer of the same structure, or the air conditioner which does not perform fan individual control, a high noise reduction effect can be acquired. That is, the air conditioner 1 according to Embodiment 1 does not need to install the number of control speakers for each quarter wavelength of the control target frequency, and can reduce the number of control speakers, thereby reducing the cost. In addition, a certain noise reduction effect can be obtained.

  Further, the blower fan control means 71 adjusts the rotational speeds of the blower fans 21 to 23 so that the amount of air radiated from the blower outlet 5 is the same when the same rotational speed control is performed as when the individual fan control is performed. Since the control is performed, noise can be reduced without deteriorating the aerodynamic performance.

  Furthermore, by dividing the air flow path of the air conditioner 1 into a plurality of regions by the partition member 54, it is possible to separate the noises radiated from the blower fans 21 to 23, respectively. Only the radiated noise is reduced, and the silencer B reduces only the noise radiated from the blower fan 23. For this reason, the crosstalk noise component by the noise radiated | emitted from the ventilation fan 22 becomes small.

  Furthermore, by dividing the air flow path of the air conditioner 1 into a plurality of regions by the partition member 54, the air flow path is brought close to the duct structure, so that noise can be captured in one dimension. For this reason, the phase of the noise transmitted inside the air conditioner 1 becomes uniform, and the phase error when the control sound interferes is reduced. Further, by reducing the rotational speed of the blower fan 22 that is not provided with the silencing mechanism, the noise in the area where the silencing mechanism is not provided is reduced, and a higher noise reduction effect is obtained compared to the configuration of FIG. Can do. Moreover, even if the air flow path of the air conditioner 1 is divided into a plurality of regions by the partition member 54, it is not necessary to install the number of control speakers for each quarter wavelength of the control target frequency, and the number of control speakers can be reduced. Therefore, the cost can be reduced and a certain noise reduction effect can be obtained.

<B. Second Embodiment>
In addition to the configuration of the first embodiment, individual fan control may be performed based on the silencing effect detected by the silencing effect detection microphone. In the second embodiment, the difference from the first embodiment will be mainly described, and the same parts as those in the first embodiment are denoted by the same reference numerals.

<B-1. Configuration>
FIG. 7 is a front view showing the configuration of the air conditioner according to Embodiment 2 of the present invention. As in the first embodiment, the air conditioner 1A according to the second embodiment constitutes an indoor unit.

  The air conditioner 1A according to the second embodiment is different from the air conditioner 1 according to the first embodiment in that the sound deadening mechanism C (the noise detection microphone 63, the control speaker 83, the noise reduction effect detection microphone 93, and the signal processing device 103). Is a point provided. The configuration of the signal processing device 103 is exactly the same as that of the signal processing devices 101 and 102 (FIG. 3). The noise detection microphone 63, the control speaker 83, and the silencing effect detection microphone 93 are attached in the same order as in the first embodiment, starting from the downstream side of the blower fan 22, the noise detection microphone 63, the control speaker 83, and the silencing effect detection microphone 93. 93 should just be installed.

  Further, the air conditioner 1 of the first embodiment is also provided with signal lines (signal lines for sending signals S1, S2, S3) connected from the signal processing devices 101 to 103 to the blower fan control means 72. And different. For this reason, the structure of the blower fan control means 72 is also different from the structure of the blower fan control means 71 according to the first embodiment. Specifically, the signals S1, S2, and S3 sent from the signal processing devices 101 to 103 to the blower fan control unit 72 are A / D converted from the signals input from the mute effect detection microphones 91 to 93 via the microphone amplifier 11. This is a signal digitally converted by the device 12 (signal S1 is shown in FIG. 3). That is, the signals S1, S2, and S3 are digital values of sound pressure levels detected by the mute effect detection microphones 91 to 93.

Next, the configuration of the blower fan control means 72 will be described.
FIG. 8 is a block diagram showing a control device according to Embodiment 2 of the present invention. Various operations and means described below are performed by executing a program incorporated in the control device 6 included in the air conditioner 1A. As in the configuration described in the first embodiment, the control device 6 mainly stores an input unit 30 for inputting a signal from an external input device such as the remote controller 7, a CPU 31 for performing operations according to an incorporated program, and data and programs. A memory 32 is provided. Further, the CPU 31 includes a blower fan control unit 72.

  The blower fan control means 72 includes the same rotation speed determination means 33, a plurality of averaging means 36 (the same number as the mute effect detection microphone), a fan individual rotation speed determination means 34A, and a plurality of SW 35 (the same number as the blower fan). . The rotation speed determination means 33 determines the rotation speed when all the blower fans 21 to 23 are operated at the same rotation speed based on the operation information input from the remote controller 7. The operation information input from the remote controller 7 is, for example, operation mode information such as a cooling operation mode, a heating operation mode, and a dehumidifying operation mode, and air volume information such as strong, medium, and weak. The averaging means 36 receives the digital values S1, S2, S3 of the sound pressure levels detected by the mute effect detection microphones 91-93, and averages these S1, S2, S3 signals for a certain period of time. To do.

  The individual fan speed determination means 34A controls the blower fans 21 to 23 based on the signals of S1, S2, and S3 averaged by the averaging means 36 and the speed information input from the same speed determination means 33. The number of rotations for individual fan control is determined. The SW 35 switches the rotation control signals of the blower fans 21 to 23 sent to the motor drivers 51 to 53 based on, for example, a signal input from the remote controller 7. That is, the SW 35 operates all the blower fans 21 to 23 at the same rotation speed (controls the same rotation speed) or operates the blower fans 21 to 23 at individual rotation speeds (whether to individually control the fans). Is to switch.

<B-2. Operation>
Next, the operation of the air conditioner 1A will be described.
As in the first embodiment, when the air conditioner 1A operates, the impellers of the blower fans 21 to 23 rotate, the indoor air is sucked in from the upper side of the blower fans 21 to 23, and to the lower side of the blower fans 21 to 23. When air is sent, airflow is generated. Along with this, an operating sound (noise) is generated in the vicinity of the air outlets of the blower fans 21 to 23, and the sound propagates downstream. The air sent by the blower fans 21 to 23 passes through the air flow path and is sent to the heat exchanger 4. For example, in the case of cooling operation, low-temperature refrigerant is sent to the heat exchanger 4 from a pipe connected to an outdoor unit (not shown). The air sent to the heat exchanger 4 is cooled by the refrigerant flowing through the heat exchanger 4 to become cold air, and is directly discharged into the room from the outlet 5.

  Also, the operation of the silencing mechanisms A to C is exactly the same as in the first embodiment, and a control sound is output so that the noise detected by the silencing effect detection microphones 91 to 93 is brought close to zero, and as a result, the silencing effect is detected. It operates to suppress noise in the microphones 91-93.

  In the case of the air conditioner 1A according to the second embodiment, in addition to the noise radiated from the blower fan 22, the silencer detection microphone 93 has noise (cross) radiated from the adjacent blower fans 21 and 23. Talk noise component) also enters. On the other hand, the crosstalk noise component detected by the silencing effect detection microphones 91 and 92 is smaller than the crosstalk noise component detected by the silencing effect detection microphone 93. This is because the silencing effect detection microphones 91 and 92 have only one adjacent blower fan (the blower fan 22). For this reason, the silencing effect of the silencing mechanisms A and B is higher than that of the silencing mechanism C.

Next, individual fan control of the blower fans 21 to 23 according to the second embodiment will be described.
Operation information selected by the remote controller 7 is input to the control device 6. As described above, the operation information is, for example, operation mode information such as a cooling operation mode, a heating operation mode, and a dehumidifying operation mode. Further, the air volume information such as strong, medium, and weak is similarly input as operation information from the remote controller 7 to the control device 6. The operation information input to the control device 6 is input to the rotation speed determination means 33 via the input unit 30. The same rotation speed determination means 33 to which the operation information is input determines the rotation speed when the blower fans 21 to 23 are controlled at the same rotation speed from the input operation information.

  On the other hand, S1 to S3 (digital values of sound pressure levels detected by the mute effect detection microphones 91 to 93) input from the signal processing devices 101 to 103 to the averaging means 36 are stored in the averaging means 36 for a certain period. Averaged.

  The sound pressure level value obtained by averaging each of S1 to S3 and the information on the rotational speed (the rotational speed at the same rotational speed control) determined by the rotational speed determining means 33 are the fan individual rotational speed determining means 34A. Is input. Based on these pieces of information, the individual fan rotational speed determination means 34A determines the rotational speed of each blower fan when performing individual fan control. Specifically, the muffler effect with a large averaged sound pressure level value is set by increasing the rotation speed of the blower fan that is close (highly related) to the muffler effect detection microphone with a small averaged sound pressure level value. The rotation speed of the blower fan is determined so as to reduce the rotation speed of the blower fan that is close to the detection microphone (highly related). At this time, it is good to determine each rotation speed of the ventilation fans 21-23 so that the air volume obtained when individual fan control is performed becomes the same air volume as that at the same rotation speed control.

  For example, in the air conditioner 1A according to the second embodiment, the average value of the noise level detected by the silencing effect detection microphone 91 is 45 dB, the average value of the noise level detected by the silencing effect detection microphone 92 is 45 dB, and the silencing effect When the average value of the noise level detected by the detection microphone 93 is 50 dB, the fan individual rotation speed determination means 34A increases the rotation speed of the blower fans 21 and 23 and decreases the rotation speed of the blower fan 22 respectively. Determine the rotation speed of the blower fan. Since the air volume and the rotational speed are in a proportional relationship, for example, in the case of the configuration shown in FIG. 7, when the rotational speed of the blower fan 21 and the blower fan 23 is increased by 10%, the rotational speed of the blower fan 22 is decreased by 20%. With the same air volume.

  In addition, the determination method of the rotation speed of the ventilation fans 21-23 mentioned above is an example to the last. For example, the average value of the noise level detected by the silencing effect detection microphone 91 is 45 dB, the average value of the noise level detected by the silencing effect detection microphone 92 is 47 dB, and the average value of the noise level detected by the silencing effect detection microphone 93 is 50 dB. If so, the rotational speed of each blower fan 21 may be determined such that the rotational speed of the blower fan 21 is increased, the rotational speed of the blower fan 22 is decreased, and the rotational speed of the blower fan 23 is left as it is. That is, the rotational speed of the blower fan 21 that is close to the silencer detection microphone 91 with the lowest detected noise level is increased, and the rotational speed of the blower fan 22 that is close to the silencer detection microphone 93 with the highest detected noise level. The rotational speed of each blower fan may be determined such that the rotational speed of the blower fan 23 that is neither of them is kept as it is.

  When an operation information signal indicating that individual fan control is performed from the remote controller 7 (for example, a signal such as a silent mode), the rotation control signal for the same speed control is changed to the rotation control signal for the individual fan control by switching the SW 35. This rotation control signal is output from the control device 6 to the blower fans 21 to 23. The rotation control signal output from the control device 6 is input to the motor drivers 51 to 53, and the blower fans 21 to 23 are controlled to the number of rotations according to the rotation control signal.

  As described above, in the case of the air conditioner 1A according to the second embodiment, the silencing effect is smaller than that in the vicinity of the silencing effect detection microphone 93 due to the magnitude of the crosstalk noise component from the adjacent blower fan. The area near the detection microphones 91 and 92 has a high silencing effect. That is, in the case of the air conditioner 1 </ b> A according to the second embodiment, the noise level detected in the area near the silencing effect detection microphones 91 and 92 is smaller than the area near the silencing effect detection microphone 93. On the other hand, the silencing effect is low in the area near the silencing effect detection microphone 93. Therefore, in the air conditioner 1A according to the second embodiment including the plurality of blower fans 21 to 23, the detected noise level among the average values of the noise level values detected by the muffling effect detection microphones 91 to 93 is detected. The rotational speed of the blower fans 21 and 23 close to the sound deadening detection microphones 91 and 92 having a small average value is increased, and the rotational speed of the blower fan 22 close to the sound deadening detection microphone 93 having a large average noise level detected. Is low.

  As a result, in the air conditioner 1A according to the second embodiment, the region where the silencing effect is high has a higher silencing effect, and the region where the silencing effect is low has less noise. Therefore, the air conditioner using a single blower fan is used. The noise radiated from the entire outlet 5 can be reduced as compared with the air conditioner that does not perform the machine and fan individual control. In other words, the air conditioner 1A according to the second embodiment does not need to install the number of control speakers for each quarter wavelength of the control target frequency, and can reduce the number of control speakers. In addition to being reduced, a certain noise reduction effect can be obtained. Furthermore, the air conditioner 1A according to the second embodiment controls aerodynamic performance by individually controlling the rotational speeds of the plurality of blower fans 21 to 23 so that the air volume is constant when the rotational speed control is performed. Can be prevented.

  Furthermore, as shown in FIGS. 9 and 10, the silencing effect can be further improved by dividing the air flow path of the air conditioner 1 </ b> A into a plurality of regions.

  FIG. 9 is a front view showing another example of the air conditioner according to Embodiment 2 of the present invention. FIG. 10 is a left side view of the air conditioner shown in FIG. In addition, FIG. 10 shows the side wall of the housing of the air conditioner 1A in a transparent manner. The air conditioner 1A shown in FIGS. 9 and 10 divides the air flow path with the partition member 54, thereby allowing the air blown by the blower fan 21 to pass through, the region through which the blown fan 22 blows air, and the blower fan 23. Is divided into areas through which air blows out. The noise detecting microphone 61, the control speaker 81, and the silencing effect detecting microphone 91 of the silencing mechanism A are arranged in an area through which the air blown out by the blower fan 21 passes. In addition, the noise detection microphone 62, the control speaker 82, and the noise reduction effect detection microphone 92 of the silencer B are disposed in a region through which the air blown out by the blower fan 23 passes. In addition, the noise detection microphone 63, the control speaker 83, and the silencing effect detection microphone 93 of the silencing mechanism C are arranged in a region through which the air blown out by the blower fan 22 passes.

  By configuring the air conditioner 1A in this way, the noise radiated from the blower fans 21 to 23 can be separated into the respective regions, and the silencing mechanism A reduces only the noise radiated from the blower fan 21. The silencing mechanism B reduces only the noise radiated from the blower fan 23, and the silencing mechanism C reduces only the noise radiated from the blower fan 22. For this reason, the crosstalk noise component (noise radiated from the blower fan provided in the adjacent flow path) detected by the noise detection microphones 61 to 63 and the silencing effect detection microphones 91 to 93 is reduced.

  Furthermore, since the air flow path is close to the duct structure, noise can be captured in one dimension. For this reason, the phase of the noise transmitted through the air conditioner 1A becomes uniform, and the phase error when the control sound interferes is reduced, so that the silencing effect is further enhanced. Therefore, by configuring the air conditioner 1A as shown in FIGS. 9 and 10, noise can be further reduced compared to the configuration of FIG. In other words, even if the air conditioner 1A is configured as shown in FIGS. 9 and 10, it is not necessary to install the number of control speakers for every quarter wavelength of the control target frequency, and the number of control speakers can be reduced. Therefore, the cost is reduced and a certain noise reduction effect can be obtained. 9 and 10, the partition member 54 is inserted in the entire air flow path. However, for example, only a part of the air flow path such as the upstream side of the heat exchanger 4 or the downstream side of the heat exchanger 4 is used. You may make it partition | separate with the partition member 54. FIG. Similarly to the first embodiment, even if there is a blower fan that is not provided with a silencer mechanism as shown in FIG. 11 (in FIG. 11, the blower fan 22 is not provided with a silencer mechanism C), the blower fan is provided. By reducing the number of rotations, the noise in the area where the silencing mechanism is not provided is reduced, and a similar silencing effect can be obtained.

  The installation positions of the noise detection microphones 61 to 63 may be anywhere as long as they are upstream of the control speakers 81 to 83. Furthermore, the installation positions of the control speakers 81 to 83 may be anywhere as long as they are downstream of the noise detection microphones 61 to 63 and upstream of the silencing effect detection microphones 91 to 93. Further, in the second embodiment, the silencing effect detection microphones 91 to 93 are arranged on substantially the extension lines of the rotation shafts of the blower fans 21 to 23. However, the silencing effect detection microphone 91 is provided on the downstream side of the control speakers 81 to 83. The installation position of ~ 93 may be anywhere. Furthermore, in the second embodiment, two to three noise detection microphones, control speakers, muffler effect detection microphones, and signal processing devices are arranged, but the present invention is not limited to this.

  In the second embodiment, the blower fan control means 72 is configured by the CPU 31 in the control device 6, but may be configured by hardware such as LSI (Large Scale Integration) or FPGA (Field Programmable Gate Array). . Further, the configuration of the blower fan control means 72 is not limited to the configuration shown in FIG.

  Moreover, in this Embodiment 2, although the case of the axial-flow fan was mentioned as an example as the several ventilation fans 21-23, it should just be a fan which blows by rotating an impeller, a sirocco fan or a line flow Of course, you may use a fan as the ventilation fans 21-23. Moreover, the ventilation fans 21-23 do not need to be provided in the upstream of the heat exchanger 4, for example, may be provided in the downstream of a heat exchanger.

  In the second embodiment, the FIR filter 18 and the LMS algorithm 19 are used for the signal processing devices 101 to 103. However, any adaptive signal processing circuit that can reduce the sound detected by the mute effect detection microphones 91 to 93 to zero. It is also possible to use a filtered-X algorithm that is generally used in the active silencing method. Further, the signal processing devices 101 to 103 do not need to be configured to perform adaptive signal processing, and may be configured to generate control sound using a fixed tap coefficient. Further, the signal processing devices 101 to 103 do not have to be digital signal processing circuits, but may be analog signal processing circuits. In the second embodiment, the configuration of the signal processing devices 101 to 103 is a 1-input 1-output system. However, the signal processing devices 101 to 103 may be configured as a multi-input multi-output system.

  In the second embodiment, the blower fan control means 72 increases the number of rotations of the blower fans 21 and 23 that are close to the noise reduction effect detection microphones 91 and 92 having a low noise level and has a high noise level. Although the configuration is such that the rotational speed of the blower fan 22 close to the effect detection microphone 93 is low, it may be configured to perform either one of them.

<B-3. Effect>
As described above, in the air conditioner 1A according to the second embodiment, a plurality of blower fans 21 to 23 are arranged, and the control device 6 that individually controls the rotational speed of the blower fans 21 to 23 (more specifically, the blower fan) Control means 72) are provided. The blower fan control means 72 is controlled so as to increase the rotation speed of the blower fan that is close to the silencer detection microphone with a small detected noise level among the average values of the noise levels detected by the silencer detection microphones 91 to 93. Then, the rotational speed control is performed so as to reduce the rotational speed of the blower fan that is close to the muffler effect detection microphone having a large detected noise level. For this reason, the region where the silencing effect is high (that is, the noise level is small) is further enhanced, and the region where the silencing effect is low (that is, the noise level is large) is low. For this reason, a noise can be reduced more compared with the air conditioner which uses a single ventilation fan with the silencing mechanism of the same structure, or the air conditioner which does not perform fan individual control. In other words, the air conditioner 1A according to the second embodiment does not need to install the number of control speakers for each quarter wavelength of the control target frequency, and can reduce the number of control speakers. In addition to being reduced, a certain noise reduction effect can be obtained.

  Further, the blower fan control means 72 adjusts the rotational speeds of the blower fans 21 to 23 so that the amount of air radiated from the blower outlet 5 is the same when the same rotational speed control is performed as when the individual fan control is performed. Since the control is performed, noise can be reduced without deteriorating the aerodynamic performance.

  Furthermore, by dividing the air flow path of the air conditioner 1 </ b> A into a plurality of regions by the partition member 54, noise radiated from the blower fans 21 to 23 can be separated, respectively. Only the radiated noise is reduced, the silencer B reduces only the noise radiated from the blower fan 23, and the silencer C reduces only the noise radiated from the blower fan 22. For this reason, in each area | region, the crosstalk noise component by the noise radiated | emitted to the adjacent area | region becomes small.

  Furthermore, by dividing the air flow path of the air conditioner 1A into a plurality of regions by the partition member 54, the air flow path is brought close to the duct structure, so that noise can be captured in one dimension. For this reason, the phase of the noise transmitted through the air conditioner 1A becomes uniform, and the phase error when the control sound interferes is reduced, so that a higher noise reduction effect can be obtained compared to the configuration of FIG. it can. Further, even when there is a blower fan that is not provided with a silencing mechanism as shown in FIG. 11, by reducing the rotational speed of the blower fan, the noise in the area where the silencer mechanism is not provided is reduced, and the same silencing effect is obtained. Can be obtained. Moreover, even if the partition member 54 divides the air flow path of the air conditioner 1A into a plurality of regions, it is not necessary to install the number of control speakers for each quarter wavelength of the control target frequency, and the number of control speakers can be reduced. Therefore, the cost can be reduced and a certain noise reduction effect can be obtained.

<C. Embodiment 3>
When performing individual fan control according to the silencing effect detected by the silencing effect detection microphone, for example, the individual fan control may be performed as follows. In the third embodiment, the differences from the first and second embodiments will be mainly described, and the same reference numerals are given to the same portions as the first and second embodiments.

<C-1. Configuration>
FIG. 12 is a front view showing a configuration of an air conditioner according to Embodiment 3 of the present invention. As in the second embodiment, the air conditioner 1B according to the third embodiment constitutes an indoor unit.

  The air conditioner 1B according to the third embodiment is different from the air conditioner 1A according to the second embodiment in that signal lines (signals T1, T2) connected from the signal processing devices 101 to 103 to the blower fan control means 73 are different. , T3 signal lines) are further provided. For this reason, the structure of the blower fan control means 73 is also different from the structure of the blower fan control means 72 according to the second embodiment. Specifically, the signals S1, S2, and S3 sent from the signal processing devices 101 to 103 to the blower fan control unit 73 are the signals input from the mute effect detection microphones 91 to 93, as in the second embodiment. The signal is digitally converted by the A / D converter 12 via the amplifier 11. That is, the signals S1, S2, and S3 are digital values of sound pressure levels detected by the mute effect detection microphones 91 to 93. The newly added signals T1, T2, and T3 are signals obtained by digitally converting the signals input from the noise detection microphones 61 to 63 through the microphone amplifier 11 by the A / D converter 12. That is, the signals T1, T2, T3 are digital values of the sound pressure level detected by the noise detection microphones 61-63.

Next, the configuration of the blower fan control means 73 will be described.
FIG. 13 is a configuration diagram illustrating a control device according to Embodiment 3 of the present invention. Various operations and means described below are performed by executing a program incorporated in the control device 6 included in the air conditioner 1B. As in the configuration described in the second embodiment, the control device 6 mainly stores an input unit 30 for inputting a signal from an external input device such as the remote control 7, a CPU 31 for performing calculations according to an incorporated program, and data and programs. A memory 32 is provided. Further, the CPU 31 includes a blower fan control means 73.

  The blower fan control means 73 includes the same rotation speed determination means 33, a plurality of coherence calculation means 37 (the same number as the mute effect detection microphone), a fan individual rotation speed determination means 34B, and a plurality of SW 35 (the same number as the blower fan). . The rotation speed determination means 33 determines the rotation speed when all the blower fans 21 to 23 are operated at the same rotation speed based on the operation information input from the remote controller 7. The operation information input from the remote controller 7 is, for example, operation mode information such as a cooling operation mode, a heating operation mode, and a dehumidifying operation mode, and air volume information such as strong, medium, and weak. The coherence calculating means 37 is a digital value S1, S2, S3 of the sound pressure level detected by the mute effect detecting microphones 91-93 and a digital value T1, T2, T3 of the sound pressure level detected by the noise detecting microphones 61-63. Is input. The coherence calculating means 37 calculates the coherence of S1 and T1, S2 and T2, and S3 and T3.

  Based on the coherence value calculated by the coherence calculating unit 37 and the rotation number information input from the same rotation number determining unit 33, the fan individual rotation number determining unit 34B controls each of the blower fans 21 to 23 when individually controlling the fans. The number of revolutions is determined. The SW 35 switches the rotation control signals of the blower fans 21 to 23 sent to the motor drivers 51 to 53 based on, for example, a signal input from the remote controller 7. That is, the SW 35 operates all the blower fans 21 to 23 at the same rotation speed (controls the same rotation speed) or operates the blower fans 21 to 23 at individual rotation speeds (whether to individually control the fans). Is to switch.

<C-2. Operation>
Next, the operation of the air conditioner 1B will be described.
As in the second embodiment, when the air conditioner 1B operates, the impellers of the blower fans 21 to 23 rotate, the indoor air is sucked in from the upper side of the blower fans 21 to 23, and to the lower side of the blower fans 21 to 23. When air is sent, airflow is generated. Along with this, an operating sound (noise) is generated in the vicinity of the air outlets of the blower fans 21 to 23, and the sound propagates downstream. The air sent by the blower fans 21 to 23 passes through the air flow path and is sent to the heat exchanger 4. For example, in the case of cooling operation, low-temperature refrigerant is sent to the heat exchanger 4 from a pipe connected to an outdoor unit (not shown). The air sent to the heat exchanger 4 is cooled by the refrigerant flowing through the heat exchanger 4 to become cold air, and is directly discharged into the room from the outlet 5.

  The operation of the silencing mechanisms A to C is exactly the same as that of the second embodiment, and the control sound is output so that the noise detected by the silencing effect detection microphones 91 to 93 is brought close to zero, and as a result, the silencing effect is detected. It operates to suppress noise in the microphones 91-93.

  In general, the silencing effect by active silencing is greatly influenced by the coherence values of the noise detection microphones 61 to 63 and the silencing effect detection microphones 91 to 93. That is, the noise reduction effect cannot be expected unless the coherence between the noise detection microphones 61 to 63 and the noise reduction effect detection microphones 91 to 93 is high. Conversely, the silencing effect can be predicted from the coherence values of the noise detection microphones 61 to 63 and the silencing effect detection microphones 91 to 93.

  Therefore, the air conditioner 1B according to the third embodiment (more specifically, the blower fan control means 73 of the control device 6) is based on the coherence values of the noise detection microphones 61 to 63 and the silencing effect detection microphones 91 to 93. The rotational speed of the blower fans 21 to 23 is controlled so as to increase the rotational speed of the blower fan in the region where the silencing effect is estimated to be high, and to reduce the rotational speed of the blower fan in the region where the silencing effect is estimated to be low. To do.

Next, individual fan control of the blower fans 21 to 23 according to the third embodiment will be described.
Operation information selected by the remote controller 7 is input to the control device 6. As described above, the operation information is, for example, operation mode information such as a cooling operation mode, a heating operation mode, and a dehumidifying operation mode. Further, the air volume information such as strong, medium, and weak is similarly input as operation information from the remote controller 7 to the control device 6. The operation information input to the control device 6 is input to the rotation speed determination means 33 via the input unit 30. The same rotation speed determination means 33 to which the operation information is input determines the rotation speed when the blower fans 21 to 23 are controlled at the same rotation speed from the input operation information.

  On the other hand, the digital values S1 to S3 of the sound pressure levels detected by the mute effect detection microphones 91 to 93 and the digital values of the sound pressure levels detected by the noise detection microphones 61 to 63, which are input from the signal processing devices 101 to 103. For T1 to T3, the coherence calculation means 37 obtains a coherence value between the microphones.

  The coherence value calculated by the coherence calculating means 37 and the information on the rotational speed determined by the same rotational speed determining means 33 (the rotational speed at the same rotational speed control) are input to the fan individual rotational speed determining means 34B. Based on these pieces of information, the individual fan speed determining unit 34B determines the rotational speed of each blower fan when performing individual fan control. Specifically, the rotation speed of the blower fan is close (highly related) to the muffler effect detection microphone with a high coherence value, and close to the silencer detection microphone with a low coherence value (highly related). The rotational speed of the blower fan is determined so as to reduce the rotational speed of the blower fan. At this time, it is good to determine each rotation speed of the ventilation fans 21-23 so that the air volume obtained when individual fan control is performed becomes the same air volume as that at the same rotation speed control.

  For example, in the air conditioner 1B according to the third embodiment, the coherence value between the noise detection microphone 61 and the silencing effect detection microphone 91 is 0.8, and the noise detection microphone 62 and the silencing effect detection microphone 92 are between When the coherence value is 0.8 and the coherence value between the noise detection microphone 63 and the muffler effect detection microphone 93 is 0.5, the fan individual rotation speed determination unit 34B determines the rotation speed of the blower fans 21 and 23. The rotational speed of each blower fan is determined so as to increase the rotational speed and lower the rotational speed of the blower fan 22. Since the air volume and the rotational speed are in a proportional relationship, for example, in the case of the configuration shown in FIG. 12, if the rotational speed of the blower fan 21 and the blower fan 23 is increased by 10%, the rotational speed of the blower fan 22 is decreased by 20%. With the same air volume.

  In addition, the determination method of the rotation speed of the ventilation fans 21-23 mentioned above is an example to the last. For example, the coherence value between the noise detection microphone 61 and the silencing effect detection microphone 91 is 0.8, the coherence value between the noise detection microphone 62 and the silencing effect detection microphone 92 is 0.7, and the noise detection microphone 63 When the coherence value with the muffler effect detection microphone 93 is 0.5, the rotational speed of the blower fan 21 is increased, the rotational speed of the blower fan 22 is decreased, and the rotational speed of the blower fan 23 is left as it is. In addition, the rotational speed of each blower fan may be determined. That is, the rotational speed of the blower fan 21 that is closest to the silencing effect detection microphone 91 having the highest coherence value is increased, and the rotational speed of the blower fan 22 that is close to the silence effect detection microphone 93 having the lowest coherence value is decreased. You may determine the rotation speed of each ventilation fan so that the rotation speed of the ventilation fan 23 which is neither of them may be left as it is.

  When an operation information signal indicating that individual fan control is performed from the remote controller 7 (for example, a signal such as a silent mode), the rotation control signal for the same speed control is changed to the rotation control signal for the individual fan control by switching the SW 35. This rotation control signal is output from the control device 6 to the blower fans 21 to 23. The rotation control signal output from the control device 6 is input to the motor drivers 51 to 53, and the blower fans 21 to 23 are controlled to the number of rotations according to the rotation control signal.

  As described above, when active silencing is used, the expected silencing effect differs depending on the coherence values of the noise detection microphones 61 to 63 and the silencing effect detection microphones 91 to 93. That is, it can be inferred that the muffling effect detection microphone with a high coherence value has a high silencing effect, and the silencing effect detection microphone with a low coherence value has a low silencing effect. Therefore, in the air conditioner 1B according to the third embodiment including the plurality of blower fans 21 to 23, the rotation speed of the blower fan close to the muffler effect detection microphone having a high coherence value is increased, and the coherence value is low. The rotation speed of the blower fan close to the muffler effect detection microphone is lowered.

  As a result, in the air conditioner 1B according to the third embodiment, the region where the silencing effect is estimated to be higher has a higher silencing effect, and the region where the silencing effect is estimated to be lower has less noise. For this reason, the noise radiated | emitted from the blower outlet 5 whole can be reduced compared with the air conditioner which does not perform the air conditioner which uses a single ventilation fan, or fan separate control. In other words, the air conditioner 1B according to the third embodiment does not need to install the number of control speakers for every ¼ wavelength of the control target frequency, and can reduce the number of control speakers. In addition to being reduced, a certain noise reduction effect can be obtained. Furthermore, the air conditioner 1B according to the third embodiment controls aerodynamic performance by individually controlling the rotational speeds of the plurality of blower fans 21 to 23 so that the air volume is constant when the rotational speed control is performed. Can be prevented.

  Furthermore, as shown in FIGS. 9 and 10 of the second embodiment, the noise reduction effect can be further improved by dividing the air flow path of the air conditioner 1B into a plurality of regions. That is, the noise radiated from the blower fans 21 to 23 can be separated into the respective areas, the silencing mechanism A reduces only the noise radiated from the blower fan 21, and the silencing mechanism B is radiated from the blower fan 23. The noise reduction mechanism C can reduce only the noise radiated from the blower fan 22. For this reason, the crosstalk noise component (noise emitted from the blower fan provided in the adjacent flow path) detected by the noise detection microphones 61 to 63 and the silencing effect detection microphones 91 to 93 is reduced.

  Furthermore, since the air flow path is close to the duct structure, noise can be captured in one dimension. For this reason, the phase of the noise transmitted inside the air conditioner 1B becomes uniform, and the phase error when the control sound is interfered is reduced, so that the silencing effect is further enhanced. Therefore, by dividing the air flow path of the air conditioner 1B into a plurality of regions, noise can be further reduced compared to the configuration of FIG. Similarly to FIG. 11 of the second embodiment, when there is a blower fan that is not provided with a silencer mechanism, the noise in the area where the silencer mechanism is not provided is reduced by lowering the rotation speed of the blower fan. A similar silencing effect can be obtained.

  Moreover, even if the air flow path of the air conditioner 1B is divided into a plurality of regions, it is not necessary to install the number of control speakers for every quarter wavelength of the control target frequency, and the number of control speakers can be reduced. Therefore, the cost is reduced and a certain noise reduction effect can be obtained. The partition member 54 does not need to be provided in the entire air flow path, and a part of the air flow path is partitioned by the partition member 54, for example, only on the upstream side of the heat exchanger 4 or only on the downstream side of the heat exchanger 4. You may do it.

  Note that the installation positions of the noise detection microphones 61 to 63 according to the third embodiment may be anywhere upstream of the control speakers 81 to 83. Furthermore, the installation positions of the control speakers 81 to 83 may be anywhere as long as they are downstream of the noise detection microphones 61 to 63 and upstream of the silencing effect detection microphones 91 to 93. Furthermore, in the third embodiment, the silencing effect detection microphones 91 to 93 are arranged on substantially the extension lines of the rotation shafts of the blower fans 21 to 23, but the silencing effect detection microphones 91 to 91 are provided on the downstream side of the control speakers 81 to 83. The installation position of 93 may be anywhere. Furthermore, in the third embodiment, three noise detection microphones, control speakers, muffler effect detection microphones, and signal processing devices are arranged, but the present invention is not limited to this.

  In the third embodiment, the blower fan control means 73 is configured by the CPU 31 in the control device 6, but may be configured by hardware such as LSI (Large Scale Integration) or FPGA (Field Programmable Gate Array). . Further, the configuration of the blower fan control means 73 is not limited to the configuration shown in FIG.

  Moreover, in this Embodiment 3, although the case of the axial flow fan was mentioned as an example as the several ventilation fans 21-23, it should just be a fan which ventilates by rotating an impeller, a sirocco fan or a line flow Of course, you may use a fan as the ventilation fans 21-23. Moreover, the ventilation fans 21-23 do not need to be provided in the upstream of the heat exchanger 4, for example, may be provided in the downstream of a heat exchanger.

  In the third embodiment, the FIR filter 18 and the LMS algorithm 19 are used in the signal processing devices 101 to 103. However, any adaptive signal processing circuit that brings the sound detected by the mute effect detection microphones 91 to 93 close to zero. It is also possible to use a filtered-X algorithm that is generally used in the active silencing method. Further, the signal processing devices 101 to 103 do not need to be configured to perform adaptive signal processing, and may be configured to generate control sound using a fixed tap coefficient. Further, the signal processing devices 101 to 103 do not have to be digital signal processing circuits, but may be analog signal processing circuits. In the third embodiment, the configuration of the signal processing devices 101 to 103 is a 1-input 1-output system. However, the signal processing devices 101 to 103 may be configured as a multi-input multi-output system.

  Moreover, in this Embodiment 3, the ventilation fan control means 73 makes the rotation speed of the ventilation fans 21 and 23 close | similar to the silencer effect detection microphones 91 and 92 with a large coherence value high, and silences with a small coherence value. Although the configuration is such that the rotational speed of the blower fan 22 close to the effect detection microphone 93 is low, it may be configured to perform either one of them.

<C-3. Effect>
As described above, in the air conditioner 1B according to the third embodiment, the plurality of blower fans 21 to 23 are arranged, and the control device 6 that individually controls the rotational speed of the blower fans 21 to 23 (more specifically, the blower fan) Control means 73) are provided. The blower fan control means 73 calculates the coherence value between the noise detection microphones 61 to 63 and the silencing effect detection microphones 91 to 93, and the rotation of the blower fan close to the silencing effect detection microphone having a high coherence value with the noise detection microphone. The number of revolutions is controlled so as to increase the number, and the number of revolutions of the blower fan that is close to the noise reduction effect detection microphone having a low coherence value with the noise detection microphone is reduced. As a result, the region where a high silencing effect can be expected has a higher silencing effect, and the region where no silencing effect can be expected has less noise. For this reason, a noise can be reduced more compared with the air conditioner which uses a single ventilation fan with the silencing mechanism of the same structure, or the air conditioner which does not perform fan individual control. In other words, the air conditioner 1B according to the third embodiment does not need to install the number of control speakers for every ¼ wavelength of the control target frequency, and can reduce the number of control speakers. In addition to being reduced, a certain noise reduction effect can be obtained.

  Further, the blower fan control means 73 adjusts the rotational speeds of the blower fans 21 to 23 so that the amount of air radiated from the blower outlet 5 becomes the same when the same rotational speed control is performed as when the individual fan control is performed. Since the control is performed, noise can be reduced without deteriorating the aerodynamic performance.

  Furthermore, by dividing the air flow path of the air conditioner 1B into a plurality of regions by the partition member 54, noise radiated from the blower fans 21 to 23 can be separated, respectively. Only the radiated noise is reduced, the silencer B reduces only the noise radiated from the blower fan 23, and the silencer C reduces only the noise radiated from the blower fan 22. For this reason, in each area | region, the crosstalk noise component by the noise radiated | emitted to the adjacent area | region becomes small.

  Furthermore, by dividing the air flow path of the air conditioner 1B into a plurality of regions by the partition member 54, the air flow path is brought close to the duct structure, so that noise can be captured in one dimension. For this reason, the phase of the noise transmitted inside the air conditioner 1B becomes uniform, and the phase error when the control sound interferes is reduced, so that a higher noise reduction effect can be obtained compared to the configuration of FIG. it can. Further, even when there is a blower fan that is not provided with a silencing mechanism, by reducing the rotation speed of the blower fan, noise in a region where the silencer mechanism is not provided is reduced, and a similar silencing effect can be obtained. . Moreover, even if the air flow path of the air conditioner 1B is divided into a plurality of regions by the partition member 54, it is not necessary to install the number of control speakers for each quarter wavelength of the control target frequency, and the number of control speakers can be reduced. Therefore, the cost can be reduced and a certain noise reduction effect can be obtained.

  Further, in the air conditioner 1B according to the third embodiment, the rotational speed is controlled based on the coherence values of the noise detection microphone and the silencing effect detection microphone. Since the theoretical silencing effect can be estimated from the coherence value, the rotation speed of the blower fan can be controlled more optimally and finely based on the coherence value of each silencing effect detection microphone. For this reason, the air conditioner 1B according to the third embodiment can obtain a higher silencing effect than the configurations of the first and second embodiments.

<D. Embodiment 4>
The silencing mechanism for carrying out the present invention is not limited to the silencing mechanism shown in the first to third embodiments. For example, even if a silencer mechanism different from the above is used, an air conditioner having the same effects as those of the first to third embodiments can be obtained. In the fourth embodiment, an example in which a different silencer mechanism is used for the air conditioner according to the first embodiment will be described. In the fourth embodiment, the difference from the above-described first to third embodiments will be mainly described, and the same parts as those in the first to third embodiments are denoted by the same reference numerals. is doing.

<D-1. Configuration>
FIG. 14 is a front view showing a configuration of an air conditioner according to Embodiment 4 of the present invention. As in the first embodiment, the air conditioner 1C according to the fourth embodiment constitutes an indoor unit.

  The difference between the air conditioner 1C according to the fourth embodiment and the air conditioner 1 according to the first embodiment is the configuration of the silencer mechanism. Specifically, in the muffling mechanism A of the air conditioner 1 according to Embodiment 1, two microphones (the noise detection microphone 61 and the muffling effect detection microphone 91) are used to perform active noise reduction. On the other hand, the silencing mechanism D used in the air conditioner 1C according to the fourth embodiment as the silencing mechanism corresponding to the silencing mechanism A is the two microphones of the silencing mechanism A (the noise detection microphone 61 and the silencing effect detection microphone 91). ) Is replaced with one microphone (noise / silence detection microphone 111). Similarly, in the muffling mechanism B of the air conditioner 1 according to Embodiment 1, two microphones (the noise detection microphone 62 and the muffling effect detection microphone 92) are used to perform active noise reduction. On the other hand, the silencing mechanism E used in the air conditioner 1C according to Embodiment 4 as the silencing mechanism corresponding to the silencing mechanism B is the two microphones of the silencing mechanism B (the noise detection microphone 62 and the silencing effect detection microphone 92). ) Is replaced with one microphone (noise / silence effect detection microphone 112). In addition, since the signal processing method differs accordingly, the air conditioner 1C according to Embodiment 4 includes signal processing devices 104 and 105 instead of the signal processing devices 101 and 102.

  That is, the silencer mechanism according to the fourth embodiment includes control speakers 81 and 82, noise / silencer effect detection microphones 111 and 112, and signal processing devices 104 and 105. The silencer D includes a control speaker 81, a noise / silencer detection microphone 111, and a signal processing device 104. The silencing mechanism E includes a control speaker 82, a noise / silencing effect detection microphone 112, and a signal processing device 105. In the fourth embodiment, the noise / muffling effect detection microphones 111 and 112 are provided at positions downstream of the control speakers 81 and 82. Further, the noise / silence effect detection microphone 111 is provided, for example, on substantially the extension line of the rotation axis of the blower fan 21, and the noise / silence effect detection microphone 112 is provided, for example, on the extension line of the rotation axis of the blower fan 23. Yes. Further, in the fourth embodiment, the noise / silencing effect detection microphones 111 and 112 are provided on the casing of the blowout nozzle forming the blowout port 5. That is, the noise / silencing effect detection microphones 111 and 112 detect the noise coming out from the outlet 5 and detect the silencing effect.

Next, the structure of the silencer mechanisms D and E according to the fourth embodiment will be described.
FIG. 15 is a block diagram showing a silencer mechanism according to Embodiment 4 of the present invention. In addition, in FIG. 15, the block diagram of the silencer mechanism D is shown. Since the silencing mechanism D and the silencing mechanism E have the same configuration, the configuration of the silencing mechanism D will be described below as a representative.

  The electric signal converted from the sound signal by the noise / muffling effect detection microphone 111 is amplified by the microphone amplifier 11 and converted from an analog signal to a digital signal by the A / D converter 12. The converted digital signal is input to the LMS algorithm 19. Further, a difference signal from the signal obtained by convolving the FIR filter 20 with the output signal of the FIR filter 18 is input to the FIR filter 18 and the LMS algorithm 19. Next, the difference signal is subjected to a convolution operation by the tap coefficient calculated by the LMS algorithm 19 in the FIR filter 18, then converted from a digital signal to an analog signal by the D / A converter 14, and amplified by the amplifier 15. The sound is emitted from the control speaker 81 as a control sound.

<D-2. Operation>
Next, the operation of the air conditioner 1C will be described.
As in the first embodiment, when the air conditioner 1C operates, the impellers of the blower fans 21 to 23 rotate, the indoor air is sucked in from the upper side of the blower fans 21 to 23, and to the lower side of the blower fans 21 to 23. When air is sent, airflow is generated. Along with this, an operating sound (noise) is generated in the vicinity of the air outlets of the blower fans 21 to 23, and the sound propagates downstream. The air sent by the blower fans 21 to 23 passes through the air flow path and is sent to the heat exchanger 4. For example, in the case of cooling operation, low-temperature refrigerant is sent to the heat exchanger 4 from a pipe connected to an outdoor unit (not shown). The air sent to the heat exchanger 4 is cooled by the refrigerant flowing through the heat exchanger 4 to become cold air, and is directly discharged into the room from the outlet 5.

Next, a method for suppressing the operation sound of the air conditioner 1C will be described. Since the silencing mechanism D and the silencing mechanism E are the same operation, the operation of the silencing mechanism D will be described below as a representative.
The sound after the control sound output from the control speaker 81 interferes with the operation sound (noise) including the blowing sound of the blowing fans 21 to 23 is detected by the noise / silence effect detection microphone 111. The noise detected by the noise / muffling effect detection microphone 111 becomes a digital signal via the microphone amplifier 11 and the A / D converter 12.

  In order to perform the same suppression method as that described in the first embodiment, it is necessary to input noise to be silenced to the FIR filter 18. Further, as shown in Expression 1, it is necessary to input the sound after the noise to be silenced as the input signal and the control sound as the error signal are interfered to the LMS algorithm 19. However, since the noise / muffling effect detection microphone 111 can only detect the sound after the control sound interferes with it, it is necessary to create noise to be muffled from the sound detected by the noise / muffling effect detection microphone 111.

  FIG. 16 shows the sound waveform after interference between the noise and the control sound (a in FIG. 16), the control sound waveform (b in FIG. 16), and the noise waveform (c in FIG. 16). Is. From the principle of sound superposition, b + c = a. Therefore, in order to obtain c from a, the difference between a and b may be taken. That is, the noise to be silenced can be created from the difference between the interference sound detected by the noise / silence effect detection microphone 111 and the control sound.

FIG. 17 shows a route from the control signal output from the FIR filter 18 as a control sound output from the control speaker 81 to the noise / silencing effect detection microphone 111 and input to the signal processing device 104. FIG.
A control signal output from the FIR filter 18 passes through a path from the D / A converter 14, the amplifier 15, and the control speaker 81 to the noise / silence effect detection microphone 111, and then the path from the microphone amplifier 11 to the A / D converter 12. Has gone through.

  Assuming that the transfer characteristic of this path is H, the FIR filter 20 in FIG. 15 estimates the transfer characteristic H. By convolving the FIR filter 20 with the output signal of the FIR filter 18, the control sound can be estimated as a signal b detected by the noise / silence effect detection microphone 111, and after the interference detected by the noise / silence effect detection microphone 111. The noise c to be silenced is generated by taking the difference from the sound a.

  The noise c to be silenced generated in this way is supplied to the LMS algorithm 19 and the FIR filter 18 as an input signal. The digital signal that has passed through the FIR filter 18 whose tap coefficient has been updated by the LMS algorithm 19 is converted into an analog signal by the D / A converter 14, amplified by the amplifier 15, and air-conditioner as a control sound from the control speaker 81. 1 is discharged into the air flow path in the body.

  On the other hand, the sound after the control sound emitted from the control speaker 81 is interfered with the noise generated from the blower fans 21 to 23 is detected by the noise / silencing effect detection microphone 111. Since the error signal of the LMS algorithm 19 described above is input with the sound detected by the noise / muffling effect detection microphone 111, the tap coefficient of the FIR filter 18 is updated so that the sound after the interference approaches zero. Will be. As a result, the noise generated from the blower fans 21 to 23 can be suppressed by the control sound that has passed through the FIR filter 18.

  As described in the first embodiment, in the active silencing method, the control speakers 81 and 82 control sound so that the noise and the silencing effect detection microphones 111 and 112 are placed in the opposite positions (control points). Is output. For this reason, the silencing effect becomes high in the vicinity of the noise / silencing effect detection microphones 111 and 112, but the phase of the control sound changes as the distance from the point increases. Therefore, the phase difference between the noise and the control sound becomes large and the silencing effect becomes low at a location away from the noise / silence effect detection microphones 111 and 112.

  Note that the individual fan control of the blower fans 21 to 23 according to the fourth embodiment is the same control as the blower fan control unit 71 described in the first embodiment.

  As described above, in the air conditioner 1C including the plurality of blower fans 21 to 23, the rotational speeds of the blower fans 21 and 23, which are close to the noise and silencing effect detection microphones 111 and 112, are increased, and the noise and silencing effect is increased. By reducing the rotational speed of the blower fan 22 that is far from the detection microphones 111 and 112, the noise and the silencing effect with a high silencing effect due to active silencing are increased, and the noise near the detecting microphones 111 and 112 is increased, and the silencing effect due to active silencing. The noise in a region far from the microphones 111 and 112 can be reduced.

  In other words, when active silencing is used, as described above, the silencing effect of the noise and silencing effect detection microphones 111 and 112 and their surroundings, which serve as control points for noise control, is enhanced, but the control speaker is located away from the control point. The phase shift between the control sound and noise radiated from 81 and 82 is increased, and the silencing effect is reduced. However, in the fourth embodiment, the air conditioner 1C is provided with a plurality of blower fans 21 to 23, so that the blower fans 21 and 23 (silencing effect) close to the noise and silencing effect detection microphones 111 and 112 are provided. Increase the rotation speed of the fan that radiates high noise), and decrease the rotation speed of the blower fan 22 (fan that radiates noise with a low noise reduction effect) far from the noise / silencing effect detection microphones 111 and 112. it can.

  As a result, in the air conditioner 1C according to the fourth embodiment, the region where the silencing effect is high further increases the silencing effect, and the region where the silencing effect is low decreases noise. Therefore, the air conditioner using a single blower fan is used. The noise radiated from the entire outlet 5 can be reduced as compared with the air conditioner that does not perform the machine and fan individual control. In other words, the air conditioner 1C according to the fourth embodiment does not need to install the number of control speakers for each quarter wavelength of the control target frequency, and can reduce the number of control speakers. In addition to being reduced, a certain noise reduction effect can be obtained. Furthermore, the air conditioner 1C according to the fourth embodiment controls aerodynamic performance by individually controlling the rotational speeds of the plurality of blower fans 21 to 23 so that the air volume is constant when the rotational speed control is performed. Can be prevented.

  Furthermore, as shown in FIGS. 18 and 19, the silencing effect can be further improved by dividing the air flow path of the air conditioner 1 </ b> C into a plurality of regions.

  FIG. 18 is a front view showing another example of the air conditioner according to Embodiment 4 of the present invention. FIG. 19 is a left side view of the air conditioner shown in FIG. Note that FIG. 19 shows the side wall of the casing of the air conditioner 1 </ b> C in a transparent manner. The air conditioner 1C shown in FIGS. 18 and 19 divides the air flow path with the partition member 54, thereby allowing the air blown by the blower fan 21 to pass through, the region through which the blown fan 22 blows air, and the blower fan 23. Is divided into areas through which air blows out. The control speaker 81 and the noise / silence effect detection microphone 111 of the silencing mechanism D are arranged in a region through which the air blown by the blower fan 21 passes. Further, the control speaker 82 and the noise / silence effect detection microphone 112 of the silencing mechanism E are arranged in a region through which the air blown by the blower fan 23 passes.

  By configuring the air conditioner 1C in this manner, the noise radiated from the blower fans 21 to 23 can be separated into the respective regions, and the muffler mechanism D reduces only the noise radiated from the blower fan 21. The silencing mechanism E reduces only the noise radiated from the blower fan 23. For this reason, it is possible to prevent the noise / silencing effect detection microphones 111 and 112 from detecting the noise radiated from the blower fan 22, so that the crosstalk noise component of the noise / silencing effect detection microphones 111 and 112 is reduced.

  Furthermore, since the air flow path is close to the duct structure, noise can be captured in one dimension. For this reason, the phase of the noise transmitted inside the air conditioner 1C becomes uniform, and the phase error when the control sound interferes is reduced, so that the silencing effect is further enhanced. Therefore, by configuring the air conditioner 1C as shown in FIGS. 18 and 19, noise can be further reduced compared to the configuration of FIG. That is, even if the air conditioner 1C is configured as shown in FIGS. 18 and 19, it is not necessary to install the number of control speakers for each quarter wavelength of the control target frequency, and the number of control speakers can be reduced. Therefore, the cost is reduced and a certain noise reduction effect can be obtained. 18 and 19, the partition member 54 is inserted in the entire air flow path. However, for example, only a part of the air flow path is arranged upstream of the heat exchanger 4 or only downstream of the heat exchanger 4. You may make it partition | separate with the partition member 54. FIG.

  In the fourth embodiment, the noise / silence effect detection microphones 111 and 112 are installed on the downstream side of the control speakers 81 and 82, but the noise / silence effect detection microphones 111 and 112 are located on the upstream side of the control speakers 81 and 82. May be installed. Furthermore, in the fourth embodiment, two control speakers, a noise / silencing effect detection microphone, and two signal processing devices are arranged, but the present invention is not limited to this.

  In the fourth embodiment, the blower fan control means 71 is configured by the CPU 31 in the control device 6, but is configured by hardware such as LSI (Large Scale Integration) or FPGA (Field Programmable Gate Array). Also good. Further, the configuration of the blower fan control means 71 is not limited to the configuration shown in FIG. 4 as in the first embodiment.

  Moreover, in this Embodiment 4, although the case of the axial flow fan was mentioned as an example as the several ventilation fans 21-23, it should just be a fan which blows by rotating an impeller, and a sirocco fan or a line flow Of course, you may use a fan as the ventilation fans 21-23. Moreover, the ventilation fans 21-23 do not need to be provided in the upstream of the heat exchanger 4, for example, may be provided in the downstream of a heat exchanger.

  In the fourth embodiment, the FIR filter 18 and the LMS algorithm 19 are used in the signal processing devices 104 and 105. However, the adaptive signal processing circuit that makes the sound detected by the noise / muffling effect detection microphones 111 and 112 close to zero is used. What is necessary is just to use the filtered-X algorithm generally used with the active muffling method. Further, the signal processing devices 104 and 105 do not need to be configured to perform adaptive signal processing, and may be configured to generate control sounds using fixed tap coefficients. The signal processing devices 104 and 105 do not have to be digital signal processing circuits, but may be analog signal processing circuits. In the fourth embodiment, the signal processing devices 104 and 105 are configured as a 1-input 1-output system. However, the signal processing devices 104 and 105 may be configured as a multi-input multi-output system.

  In the fourth embodiment, the blower fan control means 71 increases the rotational speed of the blower fans 21 and 23 that are close to the noise / silence effect detection microphones 111 and 112 and rotates the blower fan 22 that is far away. Although the number is configured to be low, it may be configured to perform either one of them.

<D-3. Effect>
As described above, in the air conditioner 1C according to the fourth embodiment, a plurality of blower fans 21 to 23 are arranged, and the control device 6 that individually controls the rotational speed of the blower fans 21 to 23 (more specifically, the blower fan) Control means 71) are provided. The blower fan control means 71 performs control so as to increase the rotational speed of the blower fans 21 and 23 that blow air to the area in the vicinity of the noise and muffler effect detection microphones 111 and 112, which are areas where the sound deadening effect is high. The rotational speed control is performed so as to reduce the rotational speed of the blower fan 22 that blows air to a region far from the noise / silencing effect detection microphones 111 and 112 that are low regions. For this reason, the region where the silencing effect is high further increases the silencing effect, and the region where the silencing effect is low has low noise. For this reason, a noise can be reduced more compared with the air conditioner which uses a single ventilation fan with the silencing mechanism of the same structure, or the air conditioner which does not perform fan individual control. That is, the air conditioner 1C according to the fourth embodiment does not need to install the number of control speakers for each quarter wavelength of the control target frequency, and can reduce the number of control speakers, thereby reducing the cost. In addition, a certain noise reduction effect can be obtained.

  Moreover, the ventilation fan control means 71 controls the rotation speed of the ventilation fans 21-23 so that it may become the same when the air volume radiated | emitted from the blower outlet 5 performs the same rotation speed control as the case where individual fan control is carried out. Therefore, noise can be reduced without degrading the aerodynamic performance.

  Furthermore, by dividing the air flow path of the air conditioner 1C into a plurality of regions by the partition member 54, noise radiated from the blower fans 21 to 23 can be separated, respectively. Only the radiated noise is reduced, and the silencer E reduces only the noise radiated from the blower fan 23. For this reason, the crosstalk noise component by the noise radiated | emitted from the ventilation fan 22 becomes small.

  Furthermore, by dividing the air flow path of the air conditioner 1C into a plurality of regions by the partition member 54, the air flow path is brought close to the duct structure, so that noise can be captured in one dimension. For this reason, the phase of the noise transmitted through the air conditioner 1C becomes uniform, and the phase error when the control sound interferes is reduced. Furthermore, by reducing the rotational speed of the blower fan 22 that is not provided with the silencing mechanism, the noise in the area where the silencing mechanism is not provided is reduced, and a high noise reduction effect can be obtained compared to the configuration of FIG. it can. Moreover, even if the partition member 54 divides the air flow path of the air conditioner 1C into a plurality of regions, it is not necessary to install the number of control speakers for each quarter wavelength of the control target frequency, and the number of control speakers can be reduced. Therefore, the cost can be reduced and a certain noise reduction effect can be obtained.

  Furthermore, in the fourth embodiment, since the noise detection microphones 61 and 62 and the silencing effect detection microphones 91 and 92 are integrated into the noise / silencing effect detection microphones 111 and 112, the number of microphones can be reduced. Since the number of points can be reduced, the cost can be further reduced.

<E. Embodiment 5>
Of course, the silencer mechanism shown in the fourth embodiment may be used for the air conditioner shown in the second embodiment. In the fifth embodiment, differences from the above-described first to fourth embodiments will be mainly described, and the same parts as those in the first to fourth embodiments are denoted by the same reference numerals. is doing.

<E-1. Configuration>
FIG. 20 is a front view showing a configuration of an air conditioner according to Embodiment 5 of the present invention. Similar to the fourth embodiment, the air conditioner 1D according to the fifth embodiment constitutes an indoor unit.

  The air conditioner 1D according to the fifth embodiment is different from the air conditioner 1C according to the fourth embodiment in that a silencer mechanism F (a control speaker 83, a noise / silent effect detection microphone 113, and a signal processing device 106) is provided. It is a point. The configuration of the signal processing device 106 is exactly the same as that of the signal processing devices 104 and 105 (FIG. 15).

  Further, as in the second embodiment, a signal line (signal line for sending signals S1, S2, S3) connected from the signal processing devices 104 to 106 to the blower fan control means 72 is also provided. It differs from the air conditioner 1C of the form 4. Signals S 1, S 2, and S 3 sent from the signal processing devices 104 to 106 to the blower fan control means 72 are signals input from the noise / silence effect detection microphones 111 to 113 through the microphone amplifier 11 to the A / D converter 12. This is a digitally converted signal. That is, the signals S1, S2, and S3 are digital values of sound pressure levels detected by the noise / silence effect detection microphones 111 to 113.

  The structure of the blower fan control means 72 is the same as that described in the second embodiment, and is the structure shown in FIG. The blower fan control means 72 includes the same rotation speed determination means 33, a plurality of averaging means 36 (the same number as the mute effect detection microphone), a fan individual rotation speed determination means 34A, and a plurality of SW 35 (the same number as the blower fan). . The rotation speed determination means 33 determines the rotation speed when all the blower fans 21 to 23 are operated at the same rotation speed based on the operation information input from the remote controller 7. The operation information input from the remote controller 7 is, for example, operation mode information such as a cooling operation mode, a heating operation mode, and a dehumidifying operation mode, and air volume information such as strong, medium, and weak. The averaging means 36 receives the digital values S1, S2, S3 of the sound pressure levels detected by the mute effect detection microphones 91-93, and averages these S1, S2, S3 signals for a certain period of time. To do.

  The individual fan speed determination means 34A controls the blower fans 21 to 23 based on the signals of S1, S2, and S3 averaged by the averaging means 36 and the speed information input from the same speed determination means 33. The number of rotations for individual fan control is determined. The SW 35 switches the rotation control signals of the blower fans 21 to 23 sent to the motor drivers 51 to 53 based on, for example, a signal input from the remote controller 7. That is, the SW 35 operates all the blower fans 21 to 23 at the same rotation speed (controls the same rotation speed) or operates the blower fans 21 to 23 at individual rotation speeds (whether to individually control the fans). Is to switch.

<E-2. Operation>
Next, the operation of the air conditioner 1D will be described.
The difference from the fourth embodiment is only the operation of the blower fan control means 72. The operation of the blower fan control means 72 is as described in the second embodiment. That is, the digital values S1 to S3 of the sound pressure level detected by the noise / silence effect detecting microphones 111 to 113 are averaged by the averaging means 36 for a certain period. Based on the averaged sound pressure level value and the rotational speed determined by the rotational speed determining means 33, the fan individual rotational speed determining means 34A determines the rotational speed of each blower fan when performing individual fan control. To do. Specifically, the muffler effect with a large averaged sound pressure level value is set by increasing the rotation speed of the blower fan that is close (highly related) to the muffler effect detection microphone with a small averaged sound pressure level value. The rotation speed of the blower fan is determined so as to reduce the rotation speed of the blower fan that is close to the detection microphone (highly related). At this time, it is good to determine each rotation speed of the ventilation fans 21-23 so that the air volume obtained when individual fan control is performed becomes the same air volume as that at the same rotation speed control.

  For example, in the air conditioner 1D according to the fifth embodiment, the average value of the noise level detected by the noise / silence effect detection microphone 111 is 45 dB, and the average value of the noise level detected by the noise / silence effect detection microphone 112 is 45 dB. If the average value of the noise level detected by the noise / silence effect detection microphone 113 is 50 dB, the fan individual rotation speed determination means 34A increases the rotation speed of the blower fans 21 and 23 and increases the rotation speed of the blower fan 22. The number of rotations of each blower fan is determined so as to lower the value. Since the air volume and the rotational speed are in a proportional relationship, for example, in the case of the configuration shown in FIG. 20, if the rotational speed of the blower fan 21 and the blower fan 23 is increased by 10%, the rotational speed of the blower fan 22 is decreased by 20%. With the same air volume.

  In addition, the determination method of the rotation speed of the ventilation fans 21-23 mentioned above is an example to the last. For example, the average value of the noise level detected by the noise / silence effect detection microphone 111 is 45 dB, the average value of the noise level detected by the noise / silence effect detection microphone 112 is 47 dB, and the noise detected by the noise / silence effect detection microphone 113 When the average level is 50 dB, the rotational speed of each blower fan is set so that the rotational speed of the blower fan 21 is increased, the rotational speed of the blower fan 22 is decreased, and the rotational speed of the blower fan 23 is left as it is. You may decide. That is, the rotational speed of the blower fan 21 that is closest to the noise / silencing effect detection microphone 111 with the lowest detected noise level is increased, and the blower fan that is close to the noise / silence effect detection microphone 113 with the highest detected noise level. The rotational speed of each blower fan may be determined so that the rotational speed of the blower fan 23 is kept low while the rotational speed of 22 is kept low.

  When an operation information signal (for example, a signal such as a silent mode) for performing individual fan control is input from the remote controller 7, the rotational speed of each blower fan is individually controlled. That is, when an operation information signal for performing individual fan control (for example, a signal such as a silent mode) is input from the remote controller 7, the rotation control in the individual fan control is performed from the rotation control signal of the same rotational speed control by switching the SW 35. The rotation control signal is output from the control device 6 to the blower fans 21 to 23. The rotation control signal output from the control device 6 is input to the motor drivers 51 to 53, and the blower fans 21 to 23 are controlled to the number of rotations according to the rotation control signal.

  Here, in the case of the air conditioner 1D according to the fifth embodiment, similarly to the second embodiment, the area near the noise / silence effect detection microphone 113 due to the magnitude of the crosstalk noise component from the adjacent blower fan As compared with the above, the noise reduction effect is higher in the area near the noise and noise reduction effect detection microphones 111 and 112. That is, compared to the area near the noise / silence effect detection microphone 113, the detected noise level is lower in the area near the noise / silence effect detection microphones 111 and 112. On the other hand, in the area near the noise / silence effect detecting microphone 113, the silencing effect is low. Therefore, in the air conditioner 1D according to the fifth embodiment including the plurality of blower fans 21 to 23, the average value of the noise level values detected by the noise / silencing effect detection microphones 111 to 113 is detected. The rotation speed of the blower fans 21 and 23 that are close to the noise / silence effect detection microphones 111 and 112 having a small average noise level is increased, and the distance to the noise / silence effect detection microphone 113 that has a large average noise level is detected. The rotation speed of the blower fan 22 is lowered.

  As a result, in the air conditioner 1D according to the fifth embodiment, the region where the silencing effect is high has a higher silencing effect, and the region where the silencing effect is low has less noise. Therefore, the air conditioner using a single blower fan is used. The noise radiated from the entire outlet 5 can be reduced as compared with the air conditioner that does not perform the machine and fan individual control. In other words, the air conditioner 1D according to the fifth embodiment does not need to install the number of control speakers for each quarter wavelength of the control target frequency, and can reduce the number of control speakers. In addition to being reduced, a certain noise reduction effect can be obtained. Furthermore, the air conditioner 1D according to the fifth embodiment performs aerodynamic performance by individually controlling the rotational speeds of the plurality of blower fans 21 to 23 so that the airflow is constant when the rotational speed control is performed. Can be prevented.

  Furthermore, as shown in FIGS. 21 and 22, the silencing effect can be further improved by dividing the air flow path of the air conditioner 1D into a plurality of regions.

  FIG. 21 is a front view showing another example of the air conditioner according to Embodiment 5 of the present invention. FIG. 22 is a left side view of the air conditioner shown in FIG. Note that FIG. 22 shows the side wall of the casing of the air conditioner 1D in a transparent manner. The air conditioner 1D shown in FIGS. 21 and 22 divides the air flow path with the partition member 54, thereby allowing the air blown by the blower fan 21 to pass through, the region through which the blown fan 22 blows air, and the blower fan 23. Is divided into areas through which air blows out. The control speaker 81 and the noise / silence effect detection microphone 111 of the silencing mechanism D are arranged in a region through which the air blown by the blower fan 21 passes. Further, the control speaker 82 and the noise / silence effect detection microphone 112 of the silencing mechanism E are arranged in a region through which the air blown by the blower fan 23 passes. Further, the control speaker 83 and the noise / silence effect detection microphone 113 of the silencing mechanism F are arranged in a region through which the air blown out by the blower fan 22 passes.

  By configuring the air conditioner 1D in this way, the noise radiated from the blower fans 21 to 23 can be separated into the respective regions, and the silencer mechanism D reduces only the noise radiated from the blower fan 21. The silencing mechanism E reduces only the noise radiated from the blower fan 23, and the silencing mechanism F reduces only the noise radiated from the blower fan 22. For this reason, the crosstalk noise component (noise radiated from the blower fan provided in the adjacent flow path) detected by the noise / muffling effect detection microphones 111 to 113 is reduced.

  Furthermore, since the air flow path is close to the duct structure, noise can be captured in one dimension. For this reason, the phase of the noise transmitted inside the air conditioner 1D becomes uniform, and the phase error when the control sound interferes is reduced, so that the silencing effect is further enhanced. Therefore, by configuring the air conditioner 1D as shown in FIGS. 21 and 22, noise can be further reduced compared to the configuration of FIG. In other words, even if the air conditioner 1D is configured as shown in FIGS. 21 and 22, it is not necessary to install the number of control speakers for every ¼ wavelength of the control target frequency, thereby reducing the number of control speakers. Therefore, the cost is reduced and a certain noise reduction effect can be obtained. 21 and 22, the partition member 54 is inserted in the entire air flow path. However, for example, only a part of the air flow path such as the upstream side of the heat exchanger 4 or the downstream side of the heat exchanger 4 is used. You may make it partition | separate with the partition member 54. FIG. Similarly to the fourth embodiment, even when there is a blower fan that is not provided with a silencer mechanism as shown in FIG. 23 (in FIG. 23, the blower fan 22 is not provided with a silencer mechanism F), the blower fan is provided. By reducing the number of rotations, the noise in the area where the silencing mechanism is not provided is reduced, and a similar silencing effect can be obtained.

  In the fifth embodiment, the noise / silence effect detection microphones 111 to 113 are installed on the downstream side of the control speakers 81 to 83, but the noise / silence effect detection microphones 111 to 113 are installed on the upstream side of the control speakers 81 to 83. May be installed. Furthermore, in the fifth embodiment, two to three control speakers, noise / muffling effect detection microphones, and signal processing devices are arranged, but the present invention is not limited to this.

  In the fifth embodiment, the blower fan control means 72 is configured by the CPU 31 in the control device 6, but is configured by hardware such as LSI (Large Scale Integration) or FPGA (Field Programmable Gate Array). Also good. Further, the configuration of the blower fan control means 72 is not limited to the configuration shown in FIG. 8 as in the second embodiment.

  Moreover, in this Embodiment 5, although the case of the axial flow fan was mentioned as an example as the several ventilation fans 21-23, it should just be a fan which blows by rotating an impeller, a sirocco fan or a line flow Of course, you may use a fan as the ventilation fans 21-23. Moreover, the ventilation fans 21-23 do not need to be provided in the upstream of the heat exchanger 4, for example, may be provided in the downstream of a heat exchanger.

  In the fifth embodiment, the FIR filter 18 and the LMS algorithm 19 are used in the signal processing devices 104 to 106. However, an adaptive signal processing circuit that brings the sound detected by the noise / silence effect detection microphones 111 to 113 close to zero. Any filter-X algorithm that is generally used in the active silencing method may be used. Further, the signal processing devices 104 to 106 do not have to be configured to perform adaptive signal processing, and may be configured to generate control sound using a fixed tap coefficient. Further, the signal processing devices 104 to 106 do not have to be digital signal processing circuits, but may be analog signal processing circuits. In the fifth embodiment, the signal processing apparatuses 104 to 106 are configured as a 1-input 1-output system, but the signal processing apparatuses 104 to 106 may be configured as a multi-input multi-output system.

  In the fifth embodiment, the blower fan control means 72 increases the number of rotations of the blower fan that is close to the noise / silence effect detection microphone with a low noise level and detects the noise / silence effect with a high noise level. Although the configuration is such that the rotational speed of the blower fan that is close to the microphone is low, it may be configured to perform either one of them.

<E-3. Effect>
As described above, in the air conditioner 1D according to the fifth embodiment, a plurality of blower fans 21 to 23 are arranged, and the control device 6 that individually controls the rotational speed of the blower fans 21 to 23 (more specifically, the blower fan) Control means 72) are provided. The blower fan control means 72 increases the rotation speed of the blower fan that is close to the noise / silence effect detection microphone with a low detected noise level among the average values of the noise levels detected by the noise / silence effect detection microphones 111 to 113. Rotational speed control is performed so as to reduce the rotational speed of the blower fan that is close to the noise / silencing effect detection microphone having a large detected noise level. For this reason, the region where the silencing effect is high (that is, the noise level is low) has a higher silencing effect, and the region where the silencing effect is low (that is, the noise level is large) has a low noise level. For this reason, a noise can be reduced more compared with the air conditioner which uses a single ventilation fan with the silencing mechanism of the same structure, or the air conditioner which does not perform fan individual control. In other words, the air conditioner 1D according to Embodiment 5 does not need to install the number of control speakers for each quarter wavelength, and can reduce the number of control speakers, thereby reducing the cost. A certain noise reduction effect can be obtained.

  Moreover, the ventilation fan control means 72 controls the rotation speed of the ventilation fans 21-23 so that it may become the same at the time of carrying out the same rotation speed control as the case where the air volume radiated | emitted from the blower outlet 5 is individual control. Therefore, noise can be reduced without degrading the aerodynamic performance.

  Furthermore, by dividing the air flow path of the air conditioner 1D into a plurality of regions by the partition member 54, it is possible to separate the noise radiated from the blower fans 21 to 23, respectively. Only the radiated noise is reduced, the silencing mechanism E reduces only the noise radiated from the blower fan 23, and the silencing mechanism F reduces only the noise radiated from the blower fan 22. For this reason, in each area | region, the crosstalk noise component by the noise radiated | emitted to the adjacent area | region becomes small.

  Furthermore, by dividing the air flow path of the air conditioner 1D into a plurality of regions by the partition member 54, the air flow path is brought close to the duct structure, so that noise can be captured in one dimension. For this reason, the phase of the noise transmitted inside the air conditioner 1D becomes uniform, and the phase error when the control sound interferes becomes small. Therefore, the silencing effect in the noise / silencing effect detection microphones 111 to 113 is increased, and noise can be further reduced as compared with the configuration of FIG. Further, even when there is a blower fan that is not provided with a silencing mechanism as shown in FIG. 23, by reducing the rotation speed of the blower fan, noise in a region where the silencer mechanism is not provided is reduced, and the same silencing effect is obtained. Can be obtained. Further, even if the air flow path of the air conditioner 1D is divided into a plurality of regions by the partition member 54, it is not necessary to install the number of control speakers for every quarter wavelength of the control target frequency, and the number of control speakers can be reduced. Therefore, the cost can be reduced and a certain noise reduction effect can be obtained.

  Furthermore, in the fifth embodiment, since the noise detection microphones 61 to 63 and the silencing effect detection microphones 91 to 93 are integrated into the noise / silencing effect detection microphones 111 to 113, the number of microphones can be reduced. The number of points can be reduced and the cost can be further reduced.

<F. Embodiment 6>
In the first to fifth embodiments, the noise reduction effect detection microphone or the noise / noise reduction effect detection microphone emits highly relevant noise (that is, the noise reduction effect detection microphone or the noise / noise reduction effect detection microphone is the noise reduction effect). The air blowing fan that emits noise that easily exhibits noise) is a blower fan that is close to the noise reduction effect detection microphone or the noise / noise reduction effect detection microphone. Not limited to this, a fan that emits noise that is highly relevant to the mute effect detection microphone or the noise / mute effect detection microphone (that is, the noise that the mute effect detection microphone or the noise / mute effect detection microphone tends to exert a mute effect) The discharging fan) may be the following blowing fan. The sixth embodiment will be described using the air conditioner according to the first embodiment as an example. Further, in the sixth embodiment, the difference from the above-described first to fifth embodiments will be mainly described, and the same parts as those in the first to fifth embodiments are denoted by the same reference numerals. is doing.

<F-1. Configuration>
As described above, the basic configuration of the air conditioner 1 according to the sixth embodiment is the same as that of FIG. 1 described in the first embodiment. The difference between the air conditioner 1 according to the sixth embodiment and the air conditioner 1 according to the first embodiment is that the blower fan information input to the memory 32 of the control device 6 is different. That is, the air conditioner 1 according to the sixth embodiment is different from the air conditioner 1 according to the first embodiment in that the blower fan information input from the memory 32 to the fan individual rotation speed determining means 34 is different. .

Further, although the detailed installation configuration of the control speakers 81 and 82 on the side surface of the air conditioner 1 has not been described in the first embodiment, in the sixth embodiment, the control speakers 81 and 82 are connected to the air as follows. It is installed on the side of the harmony machine.
Since the control speakers 81 and 82 have a certain thickness, if they are installed on the front surface or the back surface of the air conditioner 1, they block the air flow path, leading to degradation of aerodynamic performance. For this reason, in the sixth embodiment, control speakers 81 and 82 are arranged in a machine box (a box in which a control board or the like is stored, not shown) provided on both side surfaces of the casing. By arranging the control speakers 81 and 82 in this way, the control speakers 81 and 82 can be prevented from protruding into the air flow path.

  More specifically, in the first embodiment, the identification number of the blower fan that is close to the silencing effect detection microphones 91 and 92 is used as the blower fan information. On the other hand, in this Embodiment 6, the identification number of the ventilation fan installed in the both ends of the housing | casing of the air conditioner 1 is made into ventilation fan information. That is, as can be seen from FIG. 1, the blower fan information in the sixth embodiment is the identification number of the blower fan 21 and the blower fan 23.

<F-2. Operation>
The operation in the air conditioner 1 is the same as the operation described in the first embodiment. For this reason, below, the fan individual control of the ventilation fans 21-23 is demonstrated.

  Similarly to the first embodiment, the fan individual rotation speed determination means 34 of the blower fan control means 71 is based on the rotation speed information determined by the rotation speed determination means 33 and the blower fan information read from the memory 32. The number of rotations of each blower fan during control is determined. Specifically, the fan individual rotation speed determination means 34 increases the rotation speed of the blower fans 21 and 23 whose identification number is input to the memory 32, and rotates the blower fan 22 whose identification number is not input to the memory 32. Reduce the number. As a result, the fan individual rotation speed determination means 34 increases the rotation speed of the blower fans 21 and 23 installed at both ends of the casing of the air conditioner 1 and is installed at positions other than both ends of the casing of the air conditioner 1. Therefore, the rotational speed of the blower fan 22 is reduced. At this time, the rotation speeds of the blower fans 21 to 23 may be determined so that the air volume obtained when the individual fan control is performed is the same as that at the same rotation speed control.

  When an operation information signal indicating that individual fan control is performed from the remote controller 7 (for example, a signal such as a silent mode), the rotation control signal for the same speed control is changed to the rotation control signal for the individual fan control by switching the SW 35. This rotation control signal is output from the control device 6 to the blower fans 21 to 23. The rotation control signal output from the control device 6 is input to the motor drivers 51 to 53, and the blower fans 21 to 23 are controlled to the number of rotations according to the rotation control signal.

  When the noise radiated by the blower fans 21 and 23 at both ends is actively silenced and when the noise radiated by the blower fans 22 other than both ends is actively silenced, the noise of these blower fans is detected. Crosstalk noise components are different. This is because when noise radiated from the blower fan 22 is detected, noise radiated from the adjacent blower fans 21 and 23 also enters as a crosstalk noise component. For this reason, in the sixth embodiment, the air conditioner 1 is configured to include a plurality of blower fans 21 to 23, and the rotational speeds of the blower fans 21 and 23 at both ends with small crosstalk noise components are increased during noise detection. When the noise is detected, the rotational speed of the blower fan 22 other than both ends having a large crosstalk noise component is lowered.

  As a result, in the air conditioner 1 according to the sixth embodiment, the region where the silencing effect is high has a higher silencing effect, and the region where the silencing effect is low has less noise. Therefore, the air conditioner using a single blower fan is used. The noise radiated from the entire outlet 5 can be reduced as compared with the air conditioner that does not perform the machine and fan individual control. In other words, the air conditioner 1 according to Embodiment 6 does not need to install the number of control speakers for each quarter wavelength of the control target frequency, and can reduce the number of control speakers, so that the cost is low. In addition to being reduced, a certain noise reduction effect can be obtained. Furthermore, the air conditioner 1 according to the sixth embodiment controls aerodynamic performance by individually controlling the rotational speeds of the plurality of blower fans 21 to 23 so that the air volume is constant when the rotational speed control is performed. Can be prevented.

  Further, in the sixth embodiment, the control speakers 81 and 82 are installed on both side surfaces of the air conditioner 1 so that the control speakers 81 and 82 do not protrude into the air flow path. For this reason, it is possible to prevent pressure loss caused by the control speakers 81 and 82 protruding into the air flow path, and to prevent degradation of aerodynamic performance.

  Furthermore, also in the air conditioner 1 according to the sixth embodiment, the air flow path of the air conditioner 1 is divided into a plurality of regions, similarly to the air conditioner 1 shown in FIGS. 5 and 6 of the first embodiment. By dividing, the silencing effect can be further improved.

  That is, by dividing the air flow path of the air conditioner 1 into a plurality of regions by the partition member 54, the noise radiated from the blower fans 21 to 23 can be separated into the respective regions. Only the noise radiated from the fan 21 is reduced, and the silencing mechanism B reduces only the noise radiated from the blower fan 23. For this reason, since it is possible to prevent the noise detection microphones 61 and 62 and the silencing effect detection microphones 91 and 92 from detecting the noise radiated from the blower fan 22, the noise detection microphones 61 and 62 and the silencing effect detection microphone 91, 92 crosstalk noise components are reduced.

  Furthermore, since the air flow path is close to the duct structure, noise can be captured in one dimension. For this reason, the phase of the noise transmitted through the air conditioner 1 becomes uniform, and the phase error when the control sound interferes is reduced, so that the silencing effect is further enhanced. On the other hand, by reducing the rotational speed of the blower fan 22 that is not provided with the silencing mechanism, the noise in the area where the silencing mechanism is not provided is reduced. Therefore, also in the air conditioner 1 according to the sixth embodiment, by dividing the air flow path of the air conditioner 1 into a plurality of regions, noise can be further reduced compared to the configuration of FIG. That is, even if the air flow path of the air conditioner 1 according to Embodiment 6 is divided into a plurality of regions, it is not necessary to install the number of control speakers for each quarter wavelength of the control target frequency, and the control speakers Therefore, the cost can be reduced and a certain noise reduction effect can be obtained. The partition member 54 does not need to be provided in the entire air flow path, and a part of the air flow path is partitioned by the partition member 54, for example, only on the upstream side of the heat exchanger 4 or only on the downstream side of the heat exchanger 4. You may do it.

  In the sixth embodiment, the noise detection microphones 61 and 62 are installed on both sides of the air conditioner 1, but the noise detection microphones 61 and 62 may be installed anywhere as long as they are upstream of the control speakers 81 and 82. . Further, in the sixth embodiment, the control speakers 81 and 82 are arranged on both side surfaces of the air conditioner 1, but the downstream side of the noise detection microphones 61 and 62 and the upstream side of the silencing effect detection microphones 91 and 92 are provided. For example, the installation positions of the control speakers 81 and 82 may be anywhere. Furthermore, in the sixth embodiment, the silencing effect detection microphones 91 and 92 are arranged on substantially the extension lines of the rotation shafts of the blower fans 21 and 23, but the silencing effect detection microphone 91 is provided on the downstream side of the control speakers 81 and 82. 92 can be installed anywhere. Furthermore, in the sixth embodiment, two noise detection microphones, control speakers, muffler effect detection microphones, and signal processing devices are arranged, but the present invention is not limited to this.

  In the sixth embodiment, the blower fan control means 71 is configured by the CPU 31 in the control device 6, but the blower fan control means 71 is implemented by hardware such as LSI (Large Scale Integration) or FPGA (Field Programmable Gate Array). May be configured. Further, the configuration of the blower fan control means 71 is not limited to the configuration shown in FIG.

  Moreover, in this Embodiment 6, although the case of the axial flow fan was mentioned as an example as the several ventilation fans 21-23, what is necessary is just a fan which ventilates by rotating an impeller, a sirocco fan or a line flow Of course, you may use a fan as the ventilation fans 21-23. Moreover, the ventilation fans 21-23 do not need to be provided in the upstream of the heat exchanger 4, for example, may be provided in the downstream of a heat exchanger.

  Further, in the sixth embodiment, the FIR filter 18 and the LMS algorithm 19 are used for the signal processing devices 101 and 102. However, any adaptive signal processing circuit that makes the sound detected by the mute effect detection microphones 91 and 92 close to zero can be used. It is also possible to use a filtered-X algorithm that is generally used in the active silencing method. Further, the signal processing devices 101 and 102 do not need to be configured to perform adaptive signal processing, and may be configured to generate control sound using a fixed tap coefficient. Further, the signal processing devices 101 and 102 do not have to be digital signal processing circuits, but may be analog signal processing circuits. In the sixth embodiment, the signal processing apparatuses 101 and 102 are configured as a 1-input 1-output system. However, the signal processing apparatuses 101 and 102 may be configured as a multi-input multi-output system.

  Moreover, in this Embodiment 6, the ventilation fan control means 71 makes the rotation speed of the ventilation fans 21 and 23 of the both ends of the air conditioner 1 high, and makes the rotation speed of the ventilation fans 22 other than both ends low. However, it may be configured to perform either one of them.

<F-3. Effect>
As mentioned above, in the air conditioner 1 which concerns on this Embodiment 6, the several ventilation fan 21-23 is arrange | positioned and the ventilation fan control means 71 which controls the rotation speed of the ventilation fans 21-23 individually is provided. . The blower fan control means 71 controls the blower fans 21 and 23 installed at both ends of the air conditioner 1 so as to increase the number of rotations of the blower fan 22 installed at other than both ends of the air conditioner 1. Rotational speed control is performed so as to lower the rotational speed. For this reason, the region where the crosstalk noise component from the adjacent blower fan is small and the silencing effect is high further increases the silencing effect, and the region where the crosstalk noise component is large and the silencing effect is low decreases the noise. For this reason, compared with the air conditioner which uses a single ventilation fan with the silencer of the same structure, or the air conditioner which does not perform fan individual control, a high noise reduction effect can be acquired. That is, the air conditioner 1 according to Embodiment 6 does not need to install the number of control speakers for each quarter wavelength of the control target frequency, and can reduce the number of control speakers, thereby reducing the cost. In addition, a certain noise reduction effect can be obtained.

  Further, the blower fan control means 71 adjusts the rotational speeds of the blower fans 21 to 23 so that the amount of air radiated from the blower outlet 5 is the same when the same rotational speed control is performed as when the individual fan control is performed. Since the control is performed, noise can be reduced without deteriorating the aerodynamic performance.

  Furthermore, the control speakers 81 and 82 are installed on both side surfaces of the air conditioner 1 so that the control speakers 81 and 82 do not protrude into the air flow path. For this reason, it is possible to prevent pressure loss caused by the control speakers 81 and 82 protruding into the air flow path, and to prevent degradation of aerodynamic performance.

  Furthermore, by dividing the air flow path of the air conditioner 1 into a plurality of regions by the partition member 54, it is possible to separate the noises radiated from the blower fans 21 to 23, respectively. Only the radiated noise is reduced, and the silencer B reduces only the noise radiated from the blower fan 23. For this reason, the crosstalk noise component by the noise radiated | emitted from the ventilation fan 22 becomes small.

  Furthermore, by dividing the air flow path of the air conditioner 1 into a plurality of regions by the partition member 54, the air flow path is brought close to the duct structure, so that noise can be captured in one dimension. For this reason, the phase of the noise transmitted inside the air conditioner 1 becomes uniform, and the phase error when the control sound interferes is reduced. Further, by reducing the rotational speed of the blower fan 22 that is not provided with the silencing mechanism, the noise in the area where the silencing mechanism is not provided is reduced, and a higher noise reduction effect is obtained compared to the configuration of FIG. Can do. Moreover, even if the air flow path of the air conditioner 1 is divided into a plurality of regions by the partition member 54, it is not necessary to install the number of control speakers for each quarter wavelength of the control target frequency, and the number of control speakers can be reduced. Therefore, the cost can be reduced and a certain noise reduction effect can be obtained.

<G. Embodiment 7>
Of course, the air blower information shown in the sixth embodiment may be used for the air conditioner according to the fourth embodiment. In the seventh embodiment, differences from the above-described first to sixth embodiments will be mainly described, and the same parts as those in the first to sixth embodiments are denoted by the same reference numerals. is doing.

<G-1. Configuration>
The basic configuration of the air conditioner 1C according to the seventh embodiment is the same as that of FIG. 14 described in the fourth embodiment. The air conditioner 1C according to the seventh embodiment is different from the air conditioner 1C according to the fourth embodiment in that the blower fan information input to the memory 32 of the control device 6 is different. More specifically, in the seventh embodiment, the identification numbers of the blower fans installed at both ends of the casing of the air conditioner 1C are used as the blower fan information. That is, as can be seen from FIG. 14, the blower fan information in the seventh embodiment is an identification number of the blower fan 21 and the blower fan 23.

In the fourth embodiment, the detailed installation configuration of the control speakers 81 and 82 on the side of the air conditioner 1C has not been described, but in the seventh embodiment, the control speakers 81 and 82 are connected to the air as follows. It is installed on the side of the harmony machine 1C.
Since the control speakers 81 and 82 have a certain thickness, if they are installed on the front surface or the back surface of the air conditioner 1C, they block the air flow path, leading to degradation of aerodynamic performance. For this reason, in the seventh embodiment, control speakers 81 and 82 are arranged in a machine box (a box in which a control board and the like are stored, not shown) provided on both side surfaces of the casing. By arranging the control speakers 81 and 82 in this way, the control speakers 81 and 82 can be prevented from protruding into the air flow path.
<G-2. Operation>

  The operation in the air conditioner 1C is the same as the operation described in the fourth embodiment. For this reason, below, the fan individual control of the ventilation fans 21-23 is demonstrated.

  Similarly to the fourth embodiment, the fan individual rotation speed determination means 34 of the blower fan control means 71 is based on the rotation speed information determined by the rotation speed determination means 33 and the blower fan information read from the memory 32. The number of rotations of each blower fan during control is determined. Specifically, the fan individual rotation speed determination means 34 increases the rotation speed of the blower fans 21 and 23 whose identification number is input to the memory 32, and rotates the blower fan 22 whose identification number is not input to the memory 32. Reduce the number. As a result, the fan individual rotation speed determination means 34 increases the rotation speed of the blower fans 21 and 23 installed at both ends of the casing of the air conditioner 1C, and is installed at positions other than both ends of the casing of the air conditioner 1C. Therefore, the rotational speed of the blower fan 22 is reduced. At this time, the rotation speeds of the blower fans 21 to 23 may be determined so that the air volume obtained when the individual fan control is performed is the same as that at the same rotation speed control.

  When an operation information signal indicating that individual fan control is performed from the remote controller 7 (for example, a signal such as a silent mode), the rotation control signal for the same speed control is changed to the rotation control signal for the individual fan control by switching the SW 35. This rotation control signal is output from the control device 6 to the blower fans 21 to 23. The rotation control signal output from the control device 6 is input to the motor drivers 51 to 53, and the blower fans 21 to 23 are controlled to the number of rotations according to the rotation control signal.

  When the noise radiated by the blower fans 21 and 23 at both ends is actively silenced and when the noise radiated by the blower fans 22 other than both ends is actively silenced, the noise of these blower fans is detected. Crosstalk noise components are different. This is because when noise radiated from the blower fan 22 is detected, noise radiated from the adjacent blower fans 21 and 23 also enters as a crosstalk noise component. For this reason, in the seventh embodiment, the air conditioner 1C is configured to include a plurality of blower fans 21 to 23, and the rotational speeds of the blower fans 21 and 23 at both ends having a small crosstalk noise component at the time of noise detection are increased. When the noise is detected, the rotational speed of the blower fan 22 other than both ends having a large crosstalk noise component is lowered.

  As a result, in the air conditioner 1C according to the seventh embodiment, the region where the silencing effect is high has a higher silencing effect, and the region where the silencing effect is low has less noise. Therefore, the air conditioner using a single blower fan is used. The noise radiated from the entire outlet 5 can be reduced as compared with the air conditioner that does not perform the machine and fan individual control. In other words, the air conditioner 1C according to the seventh embodiment does not need to install the number of control speakers for each quarter wavelength of the control target frequency, and can reduce the number of control speakers. In addition to being reduced, a certain noise reduction effect can be obtained. Further, the air conditioner 1C according to the seventh embodiment controls aerodynamic performance by individually controlling the rotational speeds of the plurality of blower fans 21 to 23 so that the air volume is constant when the rotational speed control is performed. Can be prevented.

  Further, in the seventh embodiment, the control speakers 81 and 82 are installed on both side surfaces of the air conditioner 1C so that the control speakers 81 and 82 do not protrude into the air flow path. For this reason, it is possible to prevent pressure loss caused by the control speakers 81 and 82 protruding into the air flow path, and to prevent degradation of aerodynamic performance.

  Furthermore, also in the air conditioner 1C according to the seventh embodiment, the air flow path of the air conditioner 1C is divided into a plurality of regions, similarly to the air conditioner 1C shown in FIGS. 18 and 19 of the fourth embodiment. By dividing, the silencing effect can be further improved.

  That is, by dividing the air flow path of the air conditioner 1C into a plurality of regions by the partition member 54, the noise radiated from the blower fans 21 to 23 can be separated into the respective regions. Only the noise radiated from the fan 21 is reduced, and the silencing mechanism E reduces only the noise radiated from the blower fan 23. For this reason, since it can prevent that the noise and the silencing effect detection microphones 111 and 112 radiated | emitted from the ventilation fan 22 can detect, the crosstalk noise component of the noise and the silencing effect detection microphones 111 and 112 becomes small.

  Furthermore, since the air flow path is close to the duct structure, noise can be captured in one dimension. For this reason, the phase of the noise transmitted inside the air conditioner 1C becomes uniform, and the phase error when the control sound interferes is reduced, so that the silencing effect is further enhanced. On the other hand, by reducing the rotational speed of the blower fan 22 that is not provided with the silencing mechanism, the noise in the area where the silencing mechanism is not provided is reduced. Therefore, also in the air conditioner 1C according to the seventh embodiment, by dividing the air flow path of the air conditioner 1C into a plurality of regions, noise can be further reduced compared to the configuration of FIG. That is, even if the air flow path of the air conditioner 1C according to Embodiment 7 is divided into a plurality of regions, it is not necessary to install the number of control speakers for every quarter wavelength of the control target frequency. Therefore, the cost can be reduced and a certain noise reduction effect can be obtained. The partition member 54 does not need to be provided in the entire air flow path, and a part of the air flow path is partitioned by the partition member 54, for example, only on the upstream side of the heat exchanger 4 or only on the downstream side of the heat exchanger 4. You may do it.

  In the seventh embodiment, the noise / silencing effect detection microphones 111 and 112 are installed on the downstream side of the control speakers 81 and 82, but the noise / silence effect detection microphones 111 and 112 are arranged on the upstream side of the control speakers 81 and 82. May be installed. Furthermore, in the seventh embodiment, two control speakers, a noise / silencing effect detection microphone, and two signal processing devices are arranged, but the present invention is not limited to this.

  In the seventh embodiment, the blower fan control means 71 is configured by the CPU 31 in the control device 6, but is configured by hardware such as LSI (Large Scale Integration) or FPGA (Field Programmable Gate Array). Also good. Further, the configuration of the blower fan control means 71 is not limited to the configuration shown in FIG.

  Moreover, in this Embodiment 7, although the case of the axial flow fan was mentioned as an example as the several ventilation fans 21-23, it should just be a fan which blows by rotating an impeller, a sirocco fan or a line flow Of course, you may use a fan as the ventilation fans 21-23. Moreover, the ventilation fans 21-23 do not need to be provided in the upstream of the heat exchanger 4, for example, may be provided in the downstream of a heat exchanger.

In the seventh embodiment, the FIR filter 18 and the LMS algorithm 19 are used for the signal processing devices 104 and 105, but an adaptive signal processing circuit that brings the sound detected by the noise / muffling effect detection microphones 111 and 112 close to zero. What is necessary is just to use the filtered-X algorithm generally used with the active muffling method. Further, the signal processing devices 104 and 105 do not need to be configured to perform adaptive signal processing, and may be configured to generate control sounds using fixed tap coefficients. The signal processing devices 104 and 105 do not have to be digital signal processing circuits, but may be analog signal processing circuits.
In the seventh embodiment, the signal processing devices 104 and 105 are configured as a 1-input 1-output system. However, the signal processing devices 104 and 105 may be configured as a multi-input multi-output system.

  In the seventh embodiment, the blower fan control means 71 increases the rotational speed of the blower fans 21 and 23 at both ends of the air conditioner 1C, and lowers the rotational speed of the blower fan 22 other than both ends. However, it may be configured to perform either one of them.

<G-3. Effect>
As described above, in the air conditioner 1C according to the seventh embodiment, the plurality of blower fans 21 to 23 are arranged, and the blower fan control unit 71 that individually controls the rotational speed of the blower fans 21 to 23 is provided. . The blower fan control means 71 controls the blower fans 21 and 23 installed at both ends of the air conditioner 1C so as to increase the number of rotations of the air conditioner 1C. Rotational speed control is performed so as to lower the rotational speed. For this reason, the region where the crosstalk noise from the adjacent blower fan is small and the silencing effect is high further increases the silencing effect, and the region where the crosstalk noise is large and the silencing effect is low is reduced. For this reason, a noise can be reduced more compared with the air conditioner which uses a single ventilation fan with the silencing mechanism of the same structure, or the air conditioner which does not perform fan individual control. That is, the air conditioner 1C according to the seventh embodiment does not need to install the number of control speakers for each quarter wavelength of the control target frequency, and can reduce the number of control speakers, thereby reducing the cost. In addition, a certain noise reduction effect can be obtained.

  Further, the blower fan control means 71 adjusts the rotational speeds of the blower fans 21 to 23 so that the amount of air radiated from the blower outlet 5 is the same when the same rotational speed control is performed as when the individual fan control is performed. Since the control is performed, noise can be reduced without deteriorating the aerodynamic performance.

  Further, the control speakers 81 and 82 are installed on both side surfaces of the air conditioner 1C so that the control speakers 81 and 82 do not protrude into the air flow path. For this reason, it is possible to prevent pressure loss caused by the control speakers 81 and 82 protruding into the air flow path, and to prevent degradation of aerodynamic performance.

  Furthermore, by dividing the air flow path of the air conditioner 1C into a plurality of regions by the partition member 54, noise radiated from the blower fans 21 to 23 can be separated, respectively. Only the radiated noise is reduced, and the silencer E reduces only the noise radiated from the blower fan 23. For this reason, the crosstalk noise component by the noise radiated | emitted from the ventilation fan 22 becomes small.

  Furthermore, by dividing the air flow path of the air conditioner 1C into a plurality of regions by the partition member 54, the air flow path is brought close to the duct structure, so that noise can be captured in one dimension. For this reason, the phase of the noise transmitted through the air conditioner 1C becomes uniform, and the phase error when the control sound interferes is reduced. Further, by reducing the rotational speed of the blower fan 22 that is not provided with the silencing mechanism, the noise in the area where the silencing mechanism is not provided is reduced, and a higher noise reduction effect is obtained compared to the configuration of FIG. Can do. Moreover, even if the partition member 54 divides the air flow path of the air conditioner 1C into a plurality of regions, it is not necessary to install the number of control speakers for each quarter wavelength of the control target frequency, and the number of control speakers can be reduced. Therefore, the cost can be reduced and a certain noise reduction effect can be obtained.

  Furthermore, in the seventh embodiment, since the noise detection microphones 61 and 62 and the silencing effect detection microphones 91 and 92 are integrated into the noise / silencing effect detection microphones 111 and 112, the number of microphones can be reduced. Since the number of points can be reduced, the cost can be further reduced.

<H. Eighth Embodiment>
When performing individual fan control according to the silencing effect of the silencing effect detection microphone or the noise / silencing effect detection microphone, for example, the individual fan control may be performed as follows. In the eighth embodiment, differences from the above-described first to seventh embodiments will be mainly described, and the same parts as those in the first to seventh embodiments are denoted by the same reference numerals. is doing.

<H-1. Configuration>
FIG. 24 is a front view showing a configuration of an air conditioner according to Embodiment 8 of the present invention.
The air conditioner 1E according to the eighth embodiment constitutes an indoor unit as in the first to seventh embodiments. The basic configuration of the air conditioner 1E is substantially the same as the air conditioner 1A shown in FIG. 7 of the second embodiment.

  The air conditioner 1E according to the eighth embodiment is different from the air conditioner 1A according to the second embodiment only in the configuration of the blower fan control means 74.

The blower fan control means 74 according to the eighth embodiment will be described.
FIG. 25 is a block diagram showing a control apparatus according to Embodiment 8 of the present invention. Various operations and means described below are performed by executing a program incorporated in the control device 6 included in the air conditioner 1E. As in the configuration described in the first to seventh embodiments, the control device 6 mainly includes an input unit 30 that inputs a signal from an external input device such as the remote controller 7, a CPU 31 that performs an operation according to an embedded program, A memory 32 for storing data and programs is provided. Furthermore, the CPU 31 according to the eighth embodiment includes a blower fan control unit 74.

  The blower fan control means 74 includes the same rotation speed determination means 33, a plurality of silence volume calculation means 38 (the same number as the silencing effect detection microphone), a fan individual rotation speed determination means 34C, and a plurality of SWs 35 (the same number as the blower fan). Yes. The rotation speed determination means 33 determines the rotation speed when all the blower fans 21 to 23 are operated at the same rotation speed based on the operation information input from the remote controller 7. The operation information input from the remote controller 7 is, for example, operation mode information such as a cooling operation mode, a heating operation mode, and a dehumidifying operation mode, and air volume information such as strong, medium, and weak. The muffling volume calculation means 38 receives the digital values S1, S2 and S3 of the sound pressure levels detected by the muffling effect detection microphones 91 to 93, and calculates the muffling volume from these S1, S2 and S3 signals. To do.

  The individual fan rotation speed determination unit 34 </ b> C is based on the muffled sound volume calculated by the muffled sound volume calculation unit 38 and the fan fan information stored in the memory 32, and the respective fan rotation speeds when the fan fans 21 to 23 are individually controlled. Is to determine. The blower fan information is information on a blower fan that is highly related to the muffler effect detection microphones 91 to 93. The SW 35 switches the rotation control signals of the blower fans 21 to 23 sent to the motor drivers 51 to 53 based on, for example, a signal input from the remote controller 7. That is, the SW 35 operates all the blower fans 21 to 23 at the same rotation speed (controls the same rotation speed) or operates the blower fans 21 to 23 at individual rotation speeds (whether to individually control the fans). Is to switch.

FIG. 26 is a block diagram showing a muffled sound level calculation means according to Embodiment 8 of the present invention.
The muffled sound volume calculating means 38 averages the input signal (S1, S2 or S3), and the pre-control sound pressure level for storing the sound pressure level before starting the active mute control. A storage means 39 and a subtractor 40 are provided.

<H-2. Operation>
Next, the operation of the air conditioner 1E will be described.
As in the second embodiment, when the air conditioner 1E operates, the impellers of the blower fans 21 to 23 rotate, the indoor air is sucked in from the upper side of the blower fans 21 to 23, and to the lower side of the blower fans 21 to 23. When air is sent, airflow is generated. Along with this, an operating sound (noise) is generated in the vicinity of the air outlets of the blower fans 21 to 23, and the sound propagates downstream. The air sent by the blower fans 21 to 23 passes through the air flow path and is sent to the heat exchanger 4. For example, in the case of cooling operation, low-temperature refrigerant is sent to the heat exchanger 4 from a pipe connected to an outdoor unit (not shown). The air sent to the heat exchanger 4 is cooled by the refrigerant flowing through the heat exchanger 4 to become cold air, and is directly discharged into the room from the outlet 5.

  The operation of the silencing mechanisms A to C is exactly the same as that of the second embodiment, and the control sound is output so that the noise detected by the silencing effect detection microphones 91 to 93 is brought close to zero, and as a result, the silencing effect is detected. It operates to suppress noise in the microphones 91-93.

  In the case of the air conditioner 1E according to the eighth embodiment, in addition to the noise radiated from the blower fan 22, the silencer detection microphone 93 has noise radiated from the adjacent blower fans 21 and 23 (crosstalk noise). Ingredient) also comes in. On the other hand, the crosstalk noise component detected by the silencing effect detection microphones 91 and 92 is smaller than the crosstalk noise component detected by the silencing effect detection microphone 93. This is because the silencing effect detection microphones 91 and 92 have only one adjacent blower fan (the blower fan 22). For this reason, the silencing effect of the silencing mechanisms A and B is higher than that of the silencing mechanism C.

Next, individual fan control of the blower fans 21 to 23 according to the eighth embodiment will be described.
Operation information selected by the remote controller 7 is input to the control device 6. As described above, the operation information is, for example, operation mode information such as a cooling operation mode, a heating operation mode, and a dehumidifying operation mode. Further, the air volume information such as strong, medium, and weak is similarly input as operation information from the remote controller 7 to the control device 6. The operation information input to the control device 6 is input to the rotation speed determination means 33 via the input unit 30. The same rotation speed determination means 33 to which the operation information is input determines the rotation speed when the blower fans 21 to 23 are controlled at the same rotation speed from the input operation information. When the individual fan control is not performed, the blower fans 21 to 23 are all controlled at the same rotational speed.

  On the other hand, S1 to S3 (digital values of sound pressure levels detected by the mute effect detection microphones 91 to 93) are input from the signal processing devices 101 to 103 to the averaging unit 36 to the mute volume calculation unit 38. Further, the silence level calculation means 38 averages the sound pressure level detected by the silence effect detection microphones 91 to 93 for a certain period of time before performing the active silence control, and the averaged sound pressure level is averaged for a certain period. This is stored in the pre-control sound pressure level storage means 39. Next, the silence volume calculation means 38 averages the sound pressure level detected by the silence effect detection microphones 91 to 93 during the active silence control by the averaging means 36 for a certain period.

  Then, the muffled sound volume calculation means 38 is configured to perform “active mute control” by “the sound pressure level obtained by averaging the sound pressure levels detected by the mute effect detection microphones 91 to 93 during the active mute control for a certain period of time”. Difference from “the sound pressure level obtained by averaging the sound pressure levels detected by the mute effect detection microphones 91 to 93 before being performed by the averaging means 36 for a certain period” (stored in the pre-control sound pressure level storage means 39). From the above, the silence volume is calculated. The silence volume calculated by the silence volume calculation means 38 is input to the fan individual rotation speed determination means 34C.

  The memory 32 stores blower fan information. The blower fan information is information on a blower fan that emits noise that is most relevant to the sound detected by the muffler effect detection microphones 91 to 93. These identification numbers are assigned to each silencing effect detection microphone. In the eighth embodiment, an identification number serving as blower fan information is obtained as follows. For example, the sound detected by the muffling effect detection microphone 91 is confirmed as to which of the noises radiated from the blower fans 21 to 23 is most relevant. When the sound detected by the muffling effect detection microphone 91 is most relevant to the noise radiated from the blower fan 21, the blower fan information corresponding to the mute effect detection microphone 91 is an identification number indicating the blower fan 21. Similarly, corresponding blowing fan information is determined for the muffling effect detection microphones 92 and 93 and is stored in the memory 32 in advance.

  The determination of the blower fan information may be performed as follows, for example. For example, the noise detected from the blower fans 21 to 23 is detected by a microphone that accurately detects the blower fans 21 to 23 in a state in which the blower fans 21 to 23 are operated before product shipment. Then, the coherence value between the sound detected by these microphones and the sound detected by the mute effect detection microphone 91 is measured. Thereafter, the microphone of the detection value having the highest coherence value with respect to the detection value of the mute effect detection microphone 91 is determined. The identification number of the blower fan emitting the noise detected by the microphone is the blower fan information corresponding to the mute effect detection microphone 91. The blower fan information corresponding to the silencing effect detection microphones 92 and 93 may be determined in the same manner.

  Moreover, you may perform the determination of ventilation fan information as follows, for example. The coherence calculation means 37 as shown in the third embodiment is mounted on the blower fan control means 74 and the like of the air conditioner 1E. And the coherence value of the detection value of the noise detection microphones 61-63 and the detection value of the silencing effect detection microphones 91-93 is measured at the time of the driving | operation after product shipment. And it is good also considering the identification number of the ventilation fan close | similar to the noise detection microphone with the highest coherence value about each of the muffling effect detection microphones 91-93 as ventilation fan information.

  The method for determining the blower fan information is not limited to the above method. Any method can be used as long as it can identify a blower fan that emits noise having the highest relevance to the sound detected by the mute effect detection microphones 91 to 93.

  The silence volume calculated by the silence volume calculation means 38 and the blower fan information stored in the memory 32 are input to the fan individual rotation speed determination means 34C. Based on these pieces of information, the individual fan rotational speed determination unit 34C determines the rotational speed of each blower fan when performing individual fan control. Specifically, the rotation speed of the blower fan, which is highly related to the sound detected by the muffler effect detection microphone with a high muffled volume, is increased, and the sound detected by the muffler effect detection microphone with a low muffled volume is highly relevant. The rotational speed of the blower fan is determined so as to reduce the rotational speed of the blower fan. At this time, it is good to determine each rotation speed of the ventilation fans 21-23 so that the air volume obtained when individual fan control is performed becomes the same air volume as that at the same rotation speed control.

  For example, in the air conditioner 1E according to the eighth embodiment, the blower fan that radiates noise most highly relevant to the sound detected by the silencer detection microphone 91 is the blower fan 21, and the silencer detection microphone 92 The blower fan that radiates the noise most closely related to the sound detected in step 1 is the blower fan 23, and the blower fan that emits the noise most relevant to the sound detected by the mute effect detection microphone 93 is blown. It is assumed that it is a fan 22. It is assumed that the muffling volume in the muffling effect detection microphone 91 is -5 dB, the muffling volume in the muffling effect detection microphone 92 is -5 dB, and the muffling volume in the muffling effect detection microphone 93 is -2 dB. In this case, the fan individual rotation speed determination means 34 </ b> C determines the rotation speed of each blower fan so as to increase the rotation speed of the blower fans 21 and 23 and decrease the rotation speed of the blower fan 22. Since the air volume and the rotational speed are in a proportional relationship, for example, in the case of the configuration shown in FIG. 24, if the rotational speed of the blower fan 21 and the blower fan 23 is increased by 10%, the rotational speed of the blower fan 22 is decreased by 20%. With the same air volume.

  In addition, the determination method of the rotation speed of the ventilation fans 21-23 mentioned above is an example to the last. For example, in the air conditioner 1E according to the eighth embodiment, the blower fan that radiates noise most highly relevant to the sound detected by the silencer detection microphone 91 is the blower fan 21, and the silencer detection microphone 92 The blower fan that radiates the noise most closely related to the sound detected in step 1 is the blower fan 23, and the blower fan that emits the noise most relevant to the sound detected by the mute effect detection microphone 93 is blown. It is assumed that it is a fan 22. It is assumed that the muffled sound volume in the muffling effect detection microphone 91 is −5 dB, the muffled sound volume in the muffling effect detection microphone 92 is −3 dB, and the muffled sound volume in the muffling effect detection microphone 93 is −2 dB. In this case, the rotational speed of each blower fan 21 may be determined such that the rotational speed of the blower fan 21 is increased, the rotational speed of the blower fan 22 is decreased, and the rotational speed of the blower fan 23 is left as it is. That is, the rotation speed of the blower fan 21 that is highly related to the muffler effect detection microphone 91 having the highest muffle volume is increased, and the rotation speed of the blower fan 22 that is highly related to the muffler effect detection microphone 93 having the lowest muffle volume is decreased. However, the rotational speed of each blower fan may be determined so that the rotational speed of the blower fan 23 that is neither of them is left as it is.

  When an operation information signal indicating that individual fan control is performed from the remote controller 7 (for example, a signal such as a silent mode), the rotation control signal for the same speed control is changed to the rotation control signal for the individual fan control by switching the SW 35. This rotation control signal is output from the control device 6 to the blower fans 21 to 23. The rotation control signal output from the control device 6 is input to the motor drivers 51 to 53, and the blower fans 21 to 23 are controlled to the number of rotations according to the rotation control signal.

  As described above, in the case of the air conditioner 1E according to the eighth embodiment, the silencing effect is smaller than that in the vicinity of the silencing effect detection microphone 93 due to the magnitude of the crosstalk noise component from the adjacent blower fan. The amount of the area near the detection microphones 91 and 92 is large. On the other hand, in the area in the vicinity of the silencing effect detection microphone 93, the silencing volume is small. Therefore, in the air conditioner 1E according to the eighth embodiment including the plurality of blower fans 21 to 23, the blower fan that radiates highly relevant noise to the muffler effect detection microphones 91 and 92 having a large muffler volume. The rotation speeds of the blower fans 22 that radiate highly relevant noise to the muffler effect detection microphone 93 with a low muffled sound volume are decreased.

  As a result, the air conditioner 1E according to the eighth embodiment has a higher noise reduction effect in a region with a high noise reduction effect, and a noise reduction in a region with a low noise reduction effect. The noise radiated from the entire outlet 5 can be reduced as compared with the air conditioner that does not perform the machine and fan individual control. In other words, the air conditioner 1E according to the eighth embodiment does not need to install the number of control speakers for every ¼ wavelength of the control target frequency, and can reduce the number of control speakers. In addition to being reduced, a certain noise reduction effect can be obtained. Furthermore, the air conditioner 1E according to the eighth embodiment performs aerodynamic performance by individually controlling the rotational speeds of the plurality of blower fans 21 to 23 so that the air volume is constant when the rotational speed control is performed. Can be prevented.

  Furthermore, also in the air conditioner 1E according to the eighth embodiment, the air flow path of the air conditioner 1E is divided into a plurality of regions, similarly to the air conditioner 1A shown in FIGS. 9 and 10 of the second embodiment. By dividing, the silencing effect can be further improved.

  That is, by dividing the air flow path of the air conditioner 1E into a plurality of regions by the partition member 54, the noise radiated from the blower fans 21 to 23 can be separated into the respective regions. Only the noise radiated from the fan 21 is reduced, the silencing mechanism B reduces only the noise radiated from the blower fan 23, and the silencing mechanism C reduces only the noise radiated from the blower fan 22. For this reason, the crosstalk noise component (noise radiated from the blower fan provided in the adjacent flow path) detected by the noise detection microphones 61 to 63 and the silencing effect detection microphones 91 to 93 is reduced.

  Furthermore, since the air flow path is close to the duct structure, noise can be captured in one dimension. For this reason, the phase of the noise transmitted inside the air conditioner 1E becomes uniform, and the phase error when the control sound is interfered is reduced, so that the silencing effect is further enhanced. Therefore, also in the air conditioner 1E according to Embodiment 8, noise can be further reduced by dividing the air flow path of the air conditioner 1E into a plurality of regions as compared to the configuration of FIG. On the other hand, when there is a blower fan that is not provided with a silencing mechanism, by reducing the rotation speed of the blower fan, noise in a region where the silencer mechanism is not provided is reduced, and the same effect can be obtained. 9 and 10, the partition member 54 is inserted in the entire air flow path. However, for example, only a part of the air flow path such as the upstream side of the heat exchanger 4 or only the downstream side of the heat exchanger 4 is used. You may make it partition | separate with the partition member 54. FIG.

  In the eighth embodiment, the silencing effect detection microphones 91 to 93 are arranged on substantially the extension lines of the rotation shafts of the blower fans 21 to 23. However, the silencing effect detection microphone 91 is provided on the downstream side of the control speakers 81 to 83. The installation position of ~ 93 may be anywhere. Furthermore, in the eighth embodiment, three noise detection microphones, control speakers, muffler effect detection microphones, and signal processing devices are arranged, but the present invention is not limited to this.

  In the eighth embodiment, the blower fan control means 74 is configured by the CPU 31 in the control device 6, but may be configured by hardware such as LSI (Large Scale Integration) or FPGA (Field Programmable Gate Array). . Further, the configuration of the blower fan control means 74 is not limited to the configuration shown in FIGS.

  Moreover, in this Embodiment 8, although the case of the axial flow fan was mentioned as an example as the several ventilation fans 21-23, it should just be a fan which blows by rotating an impeller, a sirocco fan or a line flow Of course, you may use a fan as the ventilation fans 21-23. Moreover, the ventilation fans 21-23 do not need to be provided in the upstream of the heat exchanger 4, for example, may be provided in the downstream of a heat exchanger.

  In the eighth embodiment, the FIR filter 18 and the LMS algorithm 19 are used for the signal processing devices 101 to 103. However, any adaptive signal processing circuit that brings the sound detected by the mute effect detection microphones 91 to 93 close to zero. It is also possible to use a filtered-X algorithm that is generally used in the active silencing method. Further, the signal processing devices 101 to 103 do not need to be configured to perform adaptive signal processing, and may be configured to generate control sound using a fixed tap coefficient. Further, the signal processing devices 101 to 103 do not have to be digital signal processing circuits, but may be analog signal processing circuits. In the eighth embodiment, the signal processing apparatuses 101 to 103 are configured as a 1-input 1-output system. However, the signal processing apparatuses 101 to 103 may be configured as a multi-input multiple-output system.

  Further, in the eighth embodiment, the blower fan control means 74 increases the rotation speed of the blower fan that emits noise highly relevant to the sound detected by the muffler effect detection microphone having a large muffled volume, and Although the structure is such that the rotational speed of the blower fan that emits noise that is highly relevant to the sound detected by the microphone for detecting the silencing effect with a low silencing volume is reduced, it may be configured to perform either one of them. .

  Further, in the eighth embodiment, the muffled sound volume in the muffler effect detection microphones 91 to 93 is used as a parameter for controlling the rotational speed of the blower fan, but other parameters are used as parameters for controlling the rotational speed of the blower fan. Of course. For example, the average value of the sound pressure level detected by each of the muffler effect detection microphones 91 to 93 is calculated, and noise that is highly relevant to the sound detected by the muffler effect detection microphone having the largest average sound pressure level is emitted. You may make the rotation speed of the ventilation fan which is set low. Further, for example, the average value of the sound pressure level detected by each of the muffler effect detection microphones 91 to 93 is calculated, and the noise that is highly relevant to the sound detected by the muffler effect detection microphone having the smallest average value of the sound pressure level is radiated. You may make high the rotation speed of the ventilation fan currently performed. Of course, both may be performed.

  Further, as parameters for controlling the rotation speed of the blower fan, the coherence values of the noise detection microphone 61 and the silencing effect detection microphone 91, the noise detection microphone 62 and the silencing effect detection microphone 92, and the noise detection microphone 63 and the silencing effect detection microphone 93 are set. It may be used. For example, the rotational speed of the blower fan that emits noise highly relevant to the sound detected by the muffler effect detection microphone having the smallest coherence value may be lowered. Further, for example, the rotational speed of the blower fan that emits noise highly relevant to the sound detected by the muffler effect detection microphone having the largest coherence value may be increased. Of course, both may be performed.

<H-3. Effect>
As described above, in the air conditioner 1E according to the eighth embodiment, a plurality of blower fans 21 to 23 are arranged, and the control device 6 that individually controls the rotational speed of the blower fans 21 to 23 (more specifically, the blower fan) Control means 74) are provided. The blower fan control means 74 increases the rotation speed of the blower fan that emits noise highly relevant to the sound detected by the muffler effect detection microphone having a large mute volume among the mute volumes of the muffler effect detection microphones 91 to 93. The rotational speed control is performed so as to reduce the rotational speed of the blower fan that emits noise that is highly relevant to the sound detected by the muffler effect detection microphone with a low muffled sound volume. For this reason, the noise reduction effect is further enhanced by increasing the number of rotations in a region where the volume level is low, and the noise in that region is reduced by reducing the number of rotations in a region where the level level is low. For this reason, a noise can be reduced more compared with the air conditioner which uses a single ventilation fan with the silencing mechanism of the same structure, or the air conditioner which does not perform fan individual control. In other words, the air conditioner 1E according to the eighth embodiment does not need to install the number of control speakers for every ¼ wavelength of the control target frequency, and can reduce the number of control speakers. In addition to being reduced, a certain noise reduction effect can be obtained.

  Further, in the air conditioner 1E according to the eighth embodiment, since the blower fan that radiates noise highly relevant to the sound detected by the muffler effect detection microphone having a high muffled volume is specified, it is radiated. Even when a plurality of blower fans 21 to 23 having different sound pressure levels are used, the rotational speed can be accurately controlled.

  Further, the blower fan control means 74 sets the respective rotation speeds of the blower fans 21 to 23 so that the amount of air radiated from the blower outlet 5 is the same when the same rotation speed control is performed as when the individual fan control is performed. Since the control is performed, noise can be reduced without deteriorating the aerodynamic performance.

  Furthermore, by dividing the air flow path of the air conditioner 1E into a plurality of regions by the partition member 54, noises radiated from the blower fans 21 to 23 can be separated, respectively. Only the radiated noise is reduced, the silencer B reduces only the noise radiated from the blower fan 23, and the silencer C reduces only the noise radiated from the blower fan 22. For this reason, in each area | region, the crosstalk noise component by the noise radiated | emitted to the adjacent area | region becomes small.

  Furthermore, by dividing the air flow path of the air conditioner 1E into a plurality of regions by the partition member 54, the air flow path is brought close to the duct structure, so that noise can be captured in one dimension. For this reason, the phase of the noise transmitted inside the air conditioner 1E becomes uniform, and the phase error when the control sound interferes is reduced, so that a higher noise reduction effect can be obtained compared to the configuration of FIG. it can. On the other hand, when there is a region where the silencing mechanism is not provided, by reducing the rotational speed of the blower fan not provided with the silencing mechanism, the noise in that region is reduced, and a silencing effect can be obtained similarly. Further, even if the air flow path of the air conditioner 1E is divided into a plurality of regions by the partition member 54, it is not necessary to install the number of control speakers for each quarter wavelength of the control target frequency, and the number of control speakers can be reduced. Therefore, the cost can be reduced and a certain noise reduction effect can be obtained.

<I. Ninth Embodiment>
The individual fan control shown in the eighth embodiment (fan individual control using information on the blower fan that is highly relevant to the silencing effect detection microphone) is an air conditioner equipped with a silencing mechanism different from the silencing mechanism according to the eighth embodiment. It can also be implemented in the machine. Hereinafter, a case where the individual fan control shown in the eighth embodiment is adopted in the air conditioner according to the fifth embodiment will be described. In the ninth embodiment, differences from the above-described first to eighth embodiments will be mainly described, and the same parts as those in the first to eighth embodiments are denoted by the same reference numerals. is doing.

<I-1. Configuration>
FIG. 27 is a front view showing a configuration of an air conditioner according to Embodiment 9 of the present invention.
The air conditioner 1F according to the ninth embodiment constitutes an indoor unit as in the first to eighth embodiments. The basic configuration of the air conditioner 1F is substantially the same as the air conditioner 1D shown in FIG. 20 of the fifth embodiment.

  The air conditioner 1F according to the ninth embodiment is different from the air conditioner 1D according to the fifth embodiment only in the configuration of the blower fan control means 74. In addition, the structure of the ventilation fan control means 74 is completely the same as the structure shown in FIG.

<I-2. Operation>
Next, the operation of the air conditioner 1F will be described.
As in the fifth embodiment, when the air conditioner 1F operates, the impellers of the blower fans 21 to 23 rotate, the indoor air is sucked in from the upper side of the blower fans 21 to 23, and to the lower side of the blower fans 21 to 23. When air is sent, airflow is generated. Along with this, an operating sound (noise) is generated in the vicinity of the air outlets of the blower fans 21 to 23, and the sound propagates downstream. The air sent by the blower fans 21 to 23 passes through the air flow path and is sent to the heat exchanger 4. For example, in the case of cooling operation, low-temperature refrigerant is sent to the heat exchanger 4 from a pipe connected to an outdoor unit (not shown). The air sent to the heat exchanger 4 is cooled by the refrigerant flowing through the heat exchanger 4 to become cold air, and is directly discharged into the room from the outlet 5.

  Also, the operation of the silencer mechanisms D to F is exactly the same as that of the fifth embodiment, and a control sound is output so that the noise detected by the noise / silence effect detection microphones 111 to 113 approaches zero, and as a result, the noise The noise reduction effect detection microphones 111 to 113 operate so as to suppress noise.

  In the case of the air conditioner 1F according to the ninth embodiment, in addition to the noise from the blower fan 22, noise (crosstalk noise) radiated from the adjacent blower fans 21 and 23 is included in the noise / silencing effect detection microphone 113. Ingredient) also comes in. On the other hand, the crosstalk noise component detected by the noise / silence effect detection microphones 111 and 112 is smaller than the crosstalk noise component detected by the noise / silence effect detection microphone 113. This is because the noise / silencing effect detection microphones 111 and 112 have only one adjacent blower fan (the blower fan 22). For this reason, the silencing effect of the silencing mechanisms D and E is higher than that of the silencing mechanism F.

  The individual fan control of the blower fans 21 to 23 is almost the same as the contents described in the eighth embodiment. The difference between the individual fan control of the ninth embodiment and the individual fan described in the eighth embodiment is that the sounds detected by the noise / silence effect detection microphones 111 to 113 in S1 to S3 input to the muffling volume calculation means 38 are as follows. This is a digital value of the pressure level. Also, the fan individual control of the ninth embodiment is different from the fan individual control described in the eighth embodiment in that the blower fan information stored in the memory 32 is detected by the noise / silence effect detection microphones 111 to 113. This is the identification number of the blower fan that emits the noise most relevant to the sound being played.

  For this reason, the fan individual rotation speed determination unit 34C of the blower fan control unit 74 has a noise / silence level with a large silence level based on the silence level calculated by the silence level calculation unit 38 and the blower fan information stored in the memory 32. Increase the rotation speed of the blower fan, which is highly related to the sound detected by the effect detection microphone, and decrease the rotation speed of the blower fan, which is highly related to the sound detected by the noise / silence effect detection microphone, which has a low noise reduction level. Thus, the rotation speed of the blower fan is determined. At this time, it is good to determine each rotation speed of the ventilation fans 21-23 so that the air volume obtained when individual fan control is performed becomes the same air volume as that at the same rotation speed control.

  For example, in the air conditioner 1F according to the ninth embodiment, the blower fan that emits the noise most closely related to the sound detected by the noise / silence effect detection microphone 111 is the blower fan 21, and the noise / silencer The blower fan that radiates noise most relevant to the sound detected by the effect detection microphone 112 is the blower fan 23, and radiates the noise most relevant to the sound detected by the noise / silence effect detection microphone 113. Assume that the blowing fan is the blowing fan 22. It is assumed that the noise reduction level in the noise / silence effect detection microphone 111 is −5 dB, the noise reduction level in the noise / silence effect detection microphone 112 is −5 dB, and the noise reduction level in the noise / silence effect detection microphone 113 is −2 dB. In this case, the fan individual rotation speed determination means 34 </ b> C determines the rotation speed of each blower fan so as to increase the rotation speed of the blower fans 21 and 23 and decrease the rotation speed of the blower fan 22. Since the air volume and the rotational speed are in a proportional relationship, for example, in the case of the configuration shown in FIG. 27, if the rotational speed of the blower fan 21 and the blower fan 23 is increased by 10%, the rotational speed of the blower fan 22 is decreased by 20%. With the same air volume.

  In addition, the determination method of the rotation speed of the ventilation fans 21-23 mentioned above is an example to the last. In the air conditioner 1F according to the ninth embodiment, the blower fan 21 that emits the noise most closely related to the sound detected by the noise / silence effect detection microphone 111 is the blower fan 21, and the noise / silence effect detection is performed. The blower fan radiating the noise most closely related to the sound detected by the microphone 112 is the blower fan 23, and radiates the noise most closely related to the sound detected by the noise / silencing effect detection microphone 113. It is assumed that the blower fan is the blower fan 22. Then, it is assumed that the noise reduction level in the noise / silence effect detection microphone 111 is −5 dB, the noise reduction level in the noise / silence effect detection microphone 112 is −3 dB, and the noise reduction level in the noise / silence effect detection microphone 113 is −2 dB. In this case, the rotational speed of each blower fan 21 may be determined such that the rotational speed of the blower fan 21 is increased, the rotational speed of the blower fan 22 is decreased, and the rotational speed of the blower fan 23 is left as it is. That is, the rotation speed of the blower fan 21 that is highly related to the muffler effect detection microphone 91 having the highest muffle volume is increased, and the rotation speed of the blower fan 22 that is highly related to the muffler effect detection microphone 93 having the lowest muffle volume is decreased. However, the rotational speed of each blower fan may be determined so that the rotational speed of the blower fan 23 that is neither of them is left as it is.

  When an operation information signal indicating that individual fan control is performed from the remote controller 7 (for example, a signal such as a silent mode), the rotation control signal for the same speed control is changed to the rotation control signal for the individual fan control by switching the SW 35. This rotation control signal is output from the control device 6 to the blower fans 21 to 23. The rotation control signal output from the control device 6 is input to the motor drivers 51 to 53, and the blower fans 21 to 23 are controlled to the number of rotations according to the rotation control signal.

  As described above, in the case of the air conditioner 1F according to the ninth embodiment, the size of the crosstalk noise component from the adjacent blower fan is larger than that in the vicinity of the noise / muffling effect detection microphone 113. In the area in the vicinity of the noise / silencing effect detection microphones 111 and 112, the silencing volume increases. On the other hand, in the area in the vicinity of the noise / silencing effect detection microphone 113, the silencing volume is small. Therefore, in the air conditioner 1F according to the ninth embodiment including the plurality of blower fans 21 to 23, the blower fan that radiates highly relevant noise to the muffler effect detection microphones 91 and 92 having a large muffler volume. The rotation speeds of the blower fans 22 that radiate highly relevant noise to the muffler effect detection microphone 93 with a low muffled sound volume are decreased.

  As a result, in the air conditioner 1F according to the ninth embodiment, the region where the silencing effect is high further increases the silencing effect, and the region where the silencing effect is low decreases noise. Therefore, the air conditioner using a single blower fan is used. The noise radiated from the entire outlet 5 can be reduced as compared with the air conditioner that does not perform the machine and fan individual control. In other words, the air conditioner 1F according to the ninth embodiment does not need to install the number of control speakers for each quarter wavelength of the control target frequency, and can reduce the number of control speakers. In addition to being reduced, a certain noise reduction effect can be obtained. Further, the air conditioner 1F according to the ninth embodiment controls aerodynamic performance by individually controlling the rotational speeds of the plurality of blower fans 21 to 23 so that the air volume is constant when the rotational speed control is performed. Can be prevented.

  Furthermore, also in the air conditioner 1F according to the ninth embodiment, the air flow path of the air conditioner 1F is divided into a plurality of regions, similarly to the air conditioner 1D illustrated in FIGS. 21 and 22 of the fifth embodiment. By dividing, the silencing effect can be further improved.

  That is, by dividing the air flow path of the air conditioner 1F into a plurality of regions by the partition member 54, the noise radiated from the blower fans 21 to 23 can be separated into the respective regions, and the silencing mechanism D is used for blowing air. Only the noise radiated from the fan 21 is reduced, the silencing mechanism E reduces only the noise radiated from the blower fan 23, and the silencing mechanism F reduces only the noise radiated from the blower fan 22. For this reason, the crosstalk noise component (noise radiated from the blower fan provided in the adjacent flow path) detected by the noise / muffling effect detection microphones 111 to 113 is reduced.

  Furthermore, since the air flow path is close to the duct structure, noise can be captured in one dimension. For this reason, the phase of the noise transmitted inside the air conditioner 1F becomes uniform, and the phase error when the control sound interferes becomes small, so that the silencing effect becomes higher. Therefore, also in the air conditioner 1F according to Embodiment 9, noise can be further reduced by dividing the air flow path of the air conditioner 1F into a plurality of regions as compared with the configuration of FIG. On the other hand, when there is a blower fan that is not provided with a silencing mechanism, by reducing the rotation speed of the blower fan, noise in a region where the silencer mechanism is not provided is reduced, and the same effect can be obtained. 21 and 22, the partition member 54 is inserted in the entire air flow path. However, for example, only a part of the air flow path is arranged upstream of the heat exchanger 4 or only downstream of the heat exchanger 4. You may make it partition | separate with the partition member 54. FIG.

  In the ninth embodiment, the noise / silence effect detection microphones 111 to 113 are installed on the downstream side of the control speakers 81 to 83, but the noise / silence effect detection microphones 111 to 113 are installed on the upstream side of the control speakers 81 to 83. May be installed. Furthermore, in the ninth embodiment, three control speakers, noise / muffling effect detection microphones, and three signal processing devices are arranged, but the present invention is not limited to this.

  In the ninth embodiment, the blower fan control means 74 is configured by the CPU 31 in the control device 6, but is configured by hardware such as LSI (Large Scale Integration) or FPGA (Field Programmable Gate Array). Also good. Further, the configuration of the blower fan control means 74 is not limited to the configuration shown in FIG.

  Moreover, in this Embodiment 9, although the case of the axial flow fan was mentioned as an example as the several ventilation fans 21-23, it should just be a fan which blows by rotating an impeller, a sirocco fan or a line flow Of course, you may use a fan as the ventilation fans 21-23. Moreover, the ventilation fans 21-23 do not need to be provided in the upstream of the heat exchanger 4, for example, may be provided in the downstream of a heat exchanger.

  Further, in the ninth embodiment, the FIR filter 18 and the LMS algorithm 19 are used in the signal processing devices 104 to 106, but an adaptive signal processing circuit that brings the sound detected by the noise / silence effect detection microphones 111 to 113 close to zero. What is necessary is just to use the filtered-X algorithm generally used with the active muffling method. Further, the signal processing devices 104 to 106 do not have to be configured to perform adaptive signal processing, and may be configured to generate control sound using a fixed tap coefficient. Further, the signal processing devices 104 to 106 do not have to be digital signal processing circuits, but may be analog signal processing circuits. In the ninth embodiment, the signal processing devices 104 to 106 are configured as a 1-input 1-output system, but the signal processing devices 104 to 106 may be configured as a multi-input multi-output system.

  Further, in the ninth embodiment, the blower fan control means 74 increases the rotational speed of the blower fan that emits noise highly relevant to the sound detected by the muffler effect detection microphone having a large silence level, and Low noise level and noise reduction effect detection The microphone is configured to reduce the rotation speed of the blower fan that emits noise that is highly relevant to the sound detected by the microphone. Also good.

  In the ninth embodiment, the noise reduction level in the noise / silence effect detection microphones 111 to 113 is used as a parameter for controlling the rotation speed of the blower fan. However, other parameters are used as parameters for controlling the rotation speed of the blower fan. Of course, it may be used. For example, the average value of the sound pressure level detected by each of the noise / silence effect detection microphones 111 to 113 is calculated, and is highly related to the sound detected by the noise / silence effect detection microphone having the largest average sound pressure level. You may make low the rotation speed of the ventilation fan which is radiating noise. In addition, for example, the average value of the sound pressure level detected by each of the noise / silence effect detection microphones 111 to 113 is calculated, and the average value of the sound pressure level is related to the sound detected by the noise / silence effect detection microphone. You may make high the rotation speed of the ventilation fan which is radiating | emitting high noise. Of course, both may be performed.

<I-3. Effect>
As described above, in the air conditioner 1F according to the ninth embodiment, the plurality of blower fans 21 to 23 are arranged, and the control device 6 that individually controls the rotational speed of the blower fans 21 to 23 (more specifically, the blower fan) Control means 74) are provided. The blower fan control means 74 is a function of a blower fan that emits noise that is highly relevant to the sound detected by the noise / silencing effect detection microphone having a large silence level, among the silence levels in the noise / silence effect detection microphones 111 to 113. Control the rotation speed to be high, and control the rotation speed to reduce the rotation speed of the blower fan that emits noise that is highly relevant to the sound detected by the microphone with low noise reduction and noise reduction effect. . For this reason, the silencing effect is further enhanced in a region where the volume level is high, and noise is reduced in a region where the volume level is small. For this reason, a noise can be reduced more compared with the air conditioner which uses a single ventilation fan with the silencing mechanism of the same structure, or the air conditioner which does not perform fan individual control. In other words, the air conditioner 1F according to the ninth embodiment does not need to install the number of control speakers for each quarter wavelength of the control target frequency, and can reduce the number of control speakers. In addition to being reduced, a certain noise reduction effect can be obtained.

  Further, in the air conditioner 1F according to the ninth embodiment, the blower fan that radiates noise that is highly relevant to the sound detected by the noise / noise-reduction effect detection microphone having a high noise reduction volume is specified. Even when a plurality of blower fans 21 to 23 having different radiated sound pressure levels are used, the rotational speed can be accurately controlled.

  Further, the blower fan control means 74 sets the respective rotation speeds of the blower fans 21 to 23 so that the amount of air radiated from the blower outlet 5 is the same when the same rotation speed control is performed as when the individual fan control is performed. Since the control is performed, noise can be reduced without deteriorating the aerodynamic performance.

  Furthermore, by dividing the air flow path of the air conditioner 1F into a plurality of regions by the partition member 54, noises radiated from the blower fans 21 to 23 can be separated from each other. Only the radiated noise is reduced, the silencing mechanism E reduces only the noise radiated from the blower fan 23, and the silencing mechanism F reduces only the noise radiated from the blower fan 22. For this reason, in each area | region, the crosstalk noise component by the noise radiated | emitted to the adjacent area | region becomes small.

  Furthermore, by dividing the air flow path of the air conditioner 1F into a plurality of regions by the partition member 54, the air flow path is brought close to the duct structure, so that noise can be captured in one dimension. For this reason, the phase of the noise transmitted inside the air conditioner 1F becomes uniform, and the phase error when the control sound interferes is reduced, so that a higher noise reduction effect can be obtained compared to the configuration of FIG. it can. On the other hand, when there is a region where the silencing mechanism is not provided, by reducing the rotational speed of the blower fan not provided with the silencing mechanism, the noise in that region is reduced, and a silencing effect can be obtained similarly. Further, even if the air flow path of the air conditioner 1F is divided into a plurality of regions by the partition member 54, it is not necessary to install the number of control speakers for each quarter wavelength of the control target frequency, and the number of control speakers can be reduced. Therefore, the cost can be reduced and a certain noise reduction effect can be obtained.

  Furthermore, in the ninth embodiment, since the noise detection microphones 61 to 63 and the silencing effect detection microphones 91 to 93 are integrated into the noise / silence effect detection microphones 111 to 113, the number of microphones can be reduced and the number of parts can be reduced. Can be further reduced.

  1, 1A, 1B, 1C, 1D, 1E, 1F Air conditioner, 3 Suction port, 4 Heat exchanger, 5 Air outlet, 6 Control device, 7 Remote control, 11 Microphone amplifier, 12 A / D converter, 14 D / A converter, 15 amplifier, 18, 20 FIR filter, 19 LMS algorithm, 21, 22, 23 Blower fan, 30 input section, 31 CPU, 32 memory, 33 Same rotation speed determining means, 34, 34A, 34B, 34C Individual fan speed determination means, 35 SW, 36 averaging means, 37 coherence calculation means, 38 silence volume calculation means, 39 pre-control sound pressure level storage means, 40 differentiator, 51, 52, 53 motor driver, 54 partition member 61, 62, 63 Noise detection microphone, 71, 72, 73, 74 Blower fan control means, 81, 82, 83 Control speaker, 91 to 93, mute effect detection microphone, 101, 102, 103, 104, 105, 106 signal processing device, 111, 112, 113 noise / mute effect detection microphone.

Claims (36)

A housing in which an inlet and an outlet are formed;
A plurality of blower fans having an impeller and provided in the housing;
A heat exchanger provided in the housing;
A noise detection device for detecting noise radiated from the blower fan;
A control sound output device for outputting a control sound for reducing the noise;
A mute effect detecting device for detecting a mute effect by the control sound;
A control sound generation device that outputs the control sound to the control sound output device based on detection results of the noise detection device and the silencing effect detection device;
A control device that individually controls the rotational speed of the plurality of blower fans;
An air conditioner characterized by comprising:   The said control apparatus controls the rotation speed of the said several ventilation fan based on the silencing effect when the said control sound is made to interfere with the noise radiated | emitted from the said ventilation fan. The air conditioner described.   The control device changes the rotational speed of the blower fan according to the relationship between the sound detected by the silencer detection device and the blower fan based on the silence effect detected by the silencer detector. The air conditioner according to claim 1 or 2, characterized by the above. The controller is
Rotational speed control for increasing the rotational speed of the blower fan that radiates the noise most closely related to the sound detected by the silencing effect detection apparatus having a large detected silencing effect, and the silencing effect detection apparatus The rotation speed control of at least one of the rotation speed controls for lowering the rotation speed of the blower fan that emits noise having the least relevance to the detected sound is performed. Air conditioner. The controller is
The rotation speed control is performed to reduce the rotation speed of the blower fan that emits noise having the highest relevance to the sound detected by the muffler effect detection device having a small detected muffler effect. The air conditioner of Claim 3 or Claim 4. A plurality of the muffler effect detection devices;
The controller is
Based on the sound pressure level detected by a plurality of the mute detection devices,
Rotational speed control for increasing the rotational speed of the blower fan that emits noise having the highest relevance to the sound detected by the muffler effect detection device having the lowest detected sound pressure level, and the detected sound pressure level Performing at least one rotational speed control of rotational speed control for lowering the rotational speed of the blower fan that emits the noise most closely related to the sound detected by the silencing effect detecting device having the largest noise The air conditioner according to claim 3. Comprising a plurality of the noise detection devices and the silencing effect detection device,
The controller is
Calculate a coherence value between the detection value of the noise detection device and the detection value of the silencing effect detection device,
Rotational speed control for increasing the rotational speed of the blower fan that radiates the noise most closely related to the sound detected by the silencing effect detection device having the largest coherence value, and the silencing effect having the smallest coherence value The rotational speed control of at least one of the rotational speed controls for lowering the rotational speed of the blower fan that emits the noise most relevant to the sound detected by the detection device is performed. 3. The air conditioner according to 3. The controller is
A memory for storing the blower fan close to the silencing effect detecting device;
Rotational speed control for increasing the rotational speed of the blower fan close to the silencing effect detection device stored in the memory, and the other than the blower fan close to the silencing effect detection device stored in the memory The air conditioner according to claim 2 or 3, wherein at least one of the rotational speed controls for reducing the rotational speed of the blower fan is controlled. The controller is
A memory for storing the blower fan close to the silencing effect detecting device;
The rotational speed control for lowering the rotational speed of the blower fan that is close to the silencing effect detection device having a high detected sound pressure level, and the blower fan that is close to the silencer detection device having a low detected sound pressure level. The air conditioner according to claim 2 or 3, wherein at least one of the rotational speed controls for increasing the rotational speed is controlled. The controller is
A memory for storing the blower fan close to the silencing effect detecting device;
Calculate a coherence value between the detection value of the noise detection device and the detection value of the silencing effect detection device,
Rotational speed control for reducing the rotational speed of the blower fan that is close to the silencing effect detection device having a low coherence value, and rotation for increasing the rotational speed of the blower fan that is close to the silencing effect detection device having a high coherence value The air conditioner according to claim 2 or 3, wherein at least one of the number controls is controlled.   The air conditioner according to any one of claims 1 to 10, wherein the casing is divided into a plurality of regions by a partition member. The controller is
When individually controlling the rotational speed for a plurality of the blower fans,
The air conditioning according to claim 11, wherein a rotation speed control is performed to reduce a rotation speed of the blower fan provided in the area where the muffler effect detection device is not provided among the plurality of areas. Machine. The controller is
When individually controlling the rotational speed for a plurality of the blower fans,
The rotational speed control for increasing the rotational speed of the blower fan provided in the area where the silencing effect detection device is provided among a plurality of the areas is performed. The air conditioner described. The controller is
When individually controlling the rotational speed for a plurality of the blower fans,
The rotational speed control of each of the plurality of blower fans is individually performed so that the air volume is equivalent to the air volume before the rotational speed control is performed. 14. Air conditioner. A housing in which an inlet and an outlet are formed;
A plurality of blower fans having an impeller and provided in the housing;
A heat exchanger provided in the housing;
A control sound output device that outputs a control sound that reduces noise emitted from the blower fan; and
A noise / muffling effect detection device for detecting the noise and detecting a silencing effect of the control sound;
Based on the detection result of the noise / muffling effect detection device, a control sound generation device that causes the control sound output device to output the control sound;
A control device that individually controls the rotational speed of the plurality of blower fans;
An air conditioner characterized by comprising:   The said control apparatus controls the rotation speed of the said several ventilation fan based on the silencing effect when the said control sound is made to interfere with the noise radiated | emitted from the said ventilation fan. The air conditioner described.   The control device, based on the silencing effect detected by the noise / silencing effect detection device, according to the relationship between the sound detected by the noise / silencing effect detection device and the blower fan, the rotational speed of the blower fan The air conditioner according to claim 15 or 16, wherein the air conditioner is changed. The controller is
Rotational speed control for increasing the rotational speed of the blower fan that radiates noise having the highest relevance to the sound detected by the noise / silent effect detecting device having a large detected silencing effect, and the noise / silent effect The rotational speed control of at least one of the rotational speed controls for lowering the rotational speed of the blower fan that emits noise having low relevance to the sound detected by the detection device is performed. Air conditioner as described in. The controller is
Rotational speed control is performed to reduce the rotational speed of the blower fan that emits noise having the highest relevance to the sound detected by the noise / silencing effect detection device having a small detected silencing effect. The air conditioner according to claim 17 or 18. A plurality of the noise / silencing effect detection devices are provided,
The controller is
Based on the sound pressure level detected by the plurality of noise / silencing effect detection devices,
Rotational speed control for increasing the rotational speed of the blower fan that radiates the noise most closely related to the sound detected by the noise / silencing effect detection device having the lowest detected sound pressure level, and the detected sound Rotational speed of at least one of rotational speed controls for lowering the rotational speed of the blower fan that radiates the noise most closely related to the sound detected by the noise / silencing effect detection device having the highest pressure level The air conditioner according to claim 17, wherein control is performed. The controller is
A memory for storing the blower fan close to the noise / silence effect detecting device is provided,
Rotational speed control for increasing the rotational speed of the blower fan that is close to the noise / silence effect detection device stored in the memory, and the blower that is close to the noise / silence effect detection device stored in the memory The air conditioner according to claim 16 or 17, wherein at least one of the rotational speed controls for reducing the rotational speed of the blower fan other than the fan is controlled. The controller is
A memory for storing the blower fan close to the noise / silence effect detecting device is provided,
Rotational speed control for lowering the rotational speed of the blower fan, which is close to the noise / silencer effect detection device with a high detected sound pressure level, and close to the noise / silencer effect detector with a low detected sound pressure level The air conditioner according to claim 16 or 17, wherein at least one of the rotational speed controls for increasing the rotational speed of the blower fan is controlled.   The air conditioner according to any one of claims 15 to 22, wherein the casing is divided into a plurality of regions by a partition member. The controller is
When individually controlling the rotational speed for a plurality of the blower fans,
24. The rotational speed control is performed to reduce the rotational speed of the blower fan provided in the area where the noise / silencing effect detection device is not provided among the plurality of areas. Air conditioner. The controller is
When individually controlling the rotational speed for a plurality of the blower fans,
24. The rotational speed control for increasing the rotational speed of the blower fan provided in the area where the noise / silencing effect detecting device is provided among the plurality of areas is performed. 24. An air conditioner according to 24. The controller is
When individually controlling the rotational speed for a plurality of the blower fans,
26. The rotational speed control of each of the plurality of blower fans is individually performed so that the air volume is equivalent to the air volume before the rotational speed control is performed. Air conditioner. A housing in which an inlet and an outlet are formed;
A plurality of blower fans having an impeller and provided in the housing;
A heat exchanger provided in the housing;
A noise detection device for detecting noise radiated from the blower fan;
A control sound output device for outputting a control sound for reducing the noise;
A mute effect detecting device for detecting a mute effect by the control sound;
A control sound generation device that outputs the control sound to the control sound output device based on detection results of the noise detection device and the silencing effect detection device;
A control device that individually controls the rotational speed of the plurality of blower fans;
With
The controller is
Rotational speed control for increasing the rotational speed of the blower fan disposed at both ends of the casing, and rotational speed control for decreasing the rotational speed of the blower fans other than the blower fan disposed at both ends of the casing. An air conditioner characterized by performing rotation speed control of at least one of them.   The air conditioner according to claim 27, wherein the casing is divided into a plurality of regions by a partition member. The controller is
When individually controlling the rotational speed for a plurality of the blower fans,
29. The air conditioning according to claim 28, wherein a rotation speed control is performed to reduce a rotation speed of the blower fan provided in the area where the muffler effect detection device is not provided among the plurality of areas. Machine. The controller is
When individually controlling the rotational speed for a plurality of the blower fans,
30. The rotational speed control for increasing the rotational speed of the blower fan provided in the area where the silencing effect detecting device is provided among the plurality of areas is performed. The air conditioner described. The controller is
When individually controlling the rotational speed for a plurality of the blower fans,
The rotational speed control of each of the plurality of blower fans is individually performed so that the air volume is equal to the air volume before the rotational speed control is performed. Air conditioner. A housing in which an inlet and an outlet are formed;
A plurality of blower fans having an impeller and provided in the housing;
A heat exchanger provided in the housing;
A control sound output device that outputs a control sound that reduces noise emitted from the blower fan; and
A noise / muffling effect detection device for detecting the noise and detecting a silencing effect of the control sound;
Based on the detection result of the noise / muffling effect detection device, a control sound generation device that causes the control sound output device to output the control sound;
A control device that individually controls the rotational speed of the plurality of blower fans;
With
The controller is
Rotational speed control for increasing the rotational speed of the blower fan disposed at both ends of the casing, and rotational speed control for decreasing the rotational speed of the blower fans other than the blower fan disposed at both ends of the casing. An air conditioner characterized by performing rotation speed control of at least one of them.   The air conditioner according to claim 32, wherein the casing is divided into a plurality of regions by a partition member. The controller is
When individually controlling the rotational speed for a plurality of the blower fans,
34. The rotational speed control for lowering the rotational speed of the blower fan provided in the area where the noise / silencing effect detection device is not provided among the plurality of areas is performed. Air conditioner. The controller is
When individually controlling the rotational speed for a plurality of the blower fans,
34. The rotational speed control for increasing the rotational speed of the blower fan provided in the area where the noise / silencing effect detection device is provided among the plurality of areas is performed. 34. An air conditioner according to 34. The controller is
When individually controlling the rotational speed for a plurality of the blower fans,
36. The rotational speed control of each of the plurality of blower fans is individually performed so that the air volume is equivalent to the air volume before the rotational speed control is performed. 36. Air conditioner.

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