DE202012103045U1 - Air exchange device with noise control - Google Patents

Abstract

Air exchange device (1) with an acoustically controlled fan control, wherein the acoustically controlled fan control comprises: - a microphone (29), - one with the microphone (29) related evaluation unit (30), which is adapted for the evaluation of acoustic signals, the received via the microphone (29) and converted into electrical signals, - a motor controller (34) for adjusting a motor power, wherein the motor control (34) with the evaluation unit (30) is connected, - at least one electric fan (8, 12) coupled to the engine controller (34), wherein the evaluation unit (30) is adapted to increase the engine power of the at least one electric fan (8, 12) when a predetermined noise level is exceeded for a predetermined minimum period of time.

Description

In conventional air exchange devices, box-type filters are often used for cleaning the outside air flowing from outside a building into the building interior, and the exhaust air flowing in the opposite direction is used. Such box-like filters often have a plurality of juxtaposed ribs through which the outside air and the exhaust air flow. It is disadvantageous that air flowing through such box-like filter undergoes a large frictional resistance. Accordingly, the use of such box-type filters is associated with large total flow losses, which impairs the efficiency as well as the energy consumption of air exchange devices provided with such box-like filters. Furthermore, such box-like filter on a large size and are therefore unwieldy to maintain and replace.

Common air exchange devices usually include fans for the promotion of supply air in an interior of a building. The supply air is drawn in from outside the building by these fans, which are often designed as radial or axial fans. Operation of such fans produces a constant noise level from noise caused by movement of the fan. In most cases, these fans are attached directly to an opening through which the supply air flows into the building interior. As a result, the noise level of the fan in the interior of the building is clearly noticeable.

The subject matter of the present application includes an air exchange device with a microphone, wherein signals received via the microphone are used to control the fan motors and the fan motor, respectively. In one embodiment of the present application, the microphone signals are used in particular for adjusting the fan noise.

From the US 2010310083 is an electronic device with a fan and a noise suppression system is known in which a housing part of the electronic device is set depending on a microphone signal in controlled oscillations.

From the US 2003/0161490 a hood with a voice control unit is known which comprises a microphone, a speech recognition unit and a motion detector, wherein the microphone is activated on the basis of a signal of the motion detector.

The present application discloses an air exchange device with an acoustically controlled fan control. The acoustically controlled fan control has a microphone and an evaluation unit in communication with the microphone, which is set up for the evaluation of acoustic signals that are received via the microphone and converted into electrical signals.

Furthermore, the air exchange device has a motor controller connected to the evaluation unit for adjusting an engine power, and one or more electric fans connected to the engine control. In particular, the air exchange device may have an exhaust air fan for generating a exhaust air flow and a supply air fan for generating a supply air. Exhaust air and supply air can be provided as a separate fan, which is particularly advantageous in connection with a recuperative heat exchanger, but they can also be provided by one and the same fan, which is operated alternately as Zuluft- and exhaust air fan.

The air exchange device may further comprise a heat exchanger, for example a cross-flow plate heat exchanger. The heat exchanger saves energy and adapts the supply air temperature.

According to a first operating mode of the air exchange device, the evaluation unit is configured to increase the engine power of the fan or fans when a predetermined noise level is exceeded for a predetermined minimum period of time. In a more general embodiment, the evaluation unit is configured to control the engine power as a function of a predetermined noise level and a received microphone signal. A predetermined minimum period of time can be determined, for example, by counting signals from a timer of the evaluation unit.

In particular, according to the application, a sleep mode may first be activated in which the engine power is reduced. The activation of the sleep mode, for example, by the fact that a noise level for a predetermined minimum duration is exceeded or by the fact that a quiet switch was pressed.

According to a further mode of operation, the evaluation device can also be set up to increase the engine power when a predefined noise level is undershot for a predetermined minimum period of time. For example, it may be useful to aerate the room with increased power when no people are present.

Furthermore, the air exchange device may comprise a photosensor, which is connected to the evaluation unit, wherein the evaluation unit is adapted to increase the engine power when the first condition falls below a predetermined brightness and when the second condition falls below a predetermined noise level for a predetermined minimum period , This can be recognized when an interior is not lit and also no people are present and it can thus be achieved a ventilation of the room.

According to another mode, the engine power can be switched down instead of a predetermined brightness and falls below a predetermined noise level, for example, in winter, when too much heat loss is to be avoided in vacant space. For example, a user may decide which behavior is desired with an additional setting such as "Ventilate" or "Energy Saver."

The aforementioned characteristics can also be combined, in which case the noise level for upshifting at low noise intensity is substantially lower than the noise level for upshifting at high noise intensity.

Furthermore, the evaluation unit may be configured to reduce the engine power when a predetermined noise level is undershot for a predetermined minimum period of time. The reduction of the engine power can be done in particular for a predetermined minimum period of time. In this case, the reduction of the engine power may be coupled to a regulation of the fan speed, so that the reduction of the engine power is achieved indirectly via a reduction of the fan speed. By reducing the engine power or the fan speed of at least one fan, the noise level of the fan is reduced and also consumes less energy.

Furthermore, the air exchange device may include a quiet switch, wherein the evaluation unit is configured to reduce the motor power of one or more fans when the quiet switch is operated. The reduction can be made in particular for a predetermined minimum period of time. The quiet switch is advantageous, for example, in situations where it is difficult to automatically determine a criterion for turning down the fan power or rotation frequency.

In addition, the air exchange device may include a photosensor, which is connected to the evaluation unit, wherein the evaluation unit is adapted to reduce the engine power when the first condition, a predetermined brightness is exceeded and when the second condition, a predetermined noise level for a predetermined minimum period is exceeded ,

In this way, it can be prevented that the engine power is reduced when the room is dark. This is typically the case at night when there are no people present. A quiet switch can be used to reduce the fan power even in the dark, for example when the room for a slide show is darkened.

Furthermore, the air exchange device may have a receiving device for receiving control signals, such as an antenna or a line input, and a remote control with a holder for attaching the remote control to a building wall, wherein the remote control is configured to communicate with the evaluation unit via the control signals.

The remote control has a quiet switch and is configured to send a control signal to reduce the fan power to the receiver in response to an actuation of the quiet switch. Furthermore, the remote control, a microphone and an evaluation circuit which is connected to the microphone, have. This makes an elaborate filtering out of the fan noise easier or completely avoided.

Furthermore, the air exchange device may have a device for setting the predetermined volume level, so that the noise threshold can be adapted to the individual circumstances of an interior in which the air exchange device is mounted.

In particular, the air exchange device may include means for filtering fan noise, such as devices for selecting a predefined noise profile due to fan speed and for determining fan noise based on the selected noise profile, as well as devices for separating the electrical signal in the fan noise and in an external noise and to evaluate a noise level of the outside noise. The predefined noise profile can be preset statically as a factory setting or adjusted in the installed state by measurements with the microphone.

Furthermore, the motor controller may have a pulse width modulation (PWM), wherein the term "PWM" in particular also includes a phase control, and a device for adjusting a duty cycle of the pulse width modulation. Thus, the engine power can be easily adjusted based on an electronic signal.

Furthermore, the present application discloses an air exchange device with an acoustically controlled error detection, which has a microphone and an evaluation unit electrically connected to the microphone. The air exchange device further comprises a motor control, which is connected to the evaluation unit, and at least one fan motor, which is electrically connected to the motor control, and an evaluation unit which is adapted for the evaluation of acoustic signals received via the microphone and into electrical signals being transformed.

The evaluation unit comprises a device for determining a fan's own noise based on the electrical signal, a device for analyzing the fan's own noise, in particular by comparison with a predefined noise profile, and for generating an error signal based on the fan's own noise. Furthermore, the evaluation device has a device for outputting an electrical error signal if one or more predefined error conditions, such as "replace filter", "motor damaged", "motor control or power supply damaged" are met. The error signal may be an electrical error signal may be displayed, for example via a display area of the air exchange device.

Furthermore, the subject of the application comprises an air exchange device according to one of the preceding claims, wherein the evaluation unit of the air exchange device comprises a computer-readable memory with computer-readable instructions for analyzing the microphone signal.

Furthermore, the subject matter of the application comprises a remote control for an air exchange device with a microphone and with a transmission device for transmitting information detected by the microphone to a receiving device of an air exchange device. This information is information transmitting signals, in particular electrical signals. These signals can already be evaluated. For example, it may be characteristic data of the sound signals or acoustic signals or signals for downshifting or upshifting of a fan power.

The remote control may further include an evaluation unit for generating the information detected with the microphone. The information detected with the microphone in this case includes a signal for downshifting a fan power of a fan of the air exchange device.

Furthermore, a remote control according to the application may also include a quiet switch, the remote control being configured to send a control signal for reducing a fan power of the air exchange device to the receiving device of the air exchange device in response to an operation of the quiet switch.

According to a further aspect of the present application, an air exchange device with an active noise suppression is disclosed which comprises a microphone and an evaluation unit in communication with the microphone. The evaluation unit is set up for the evaluation of acoustic signals that are received via the microphone and converted into electrical signals, as well as for generating and transmitting a compensation signal to a loudspeaker of the air exchange device. This compensation signal is based on the signals received via the microphone.

Furthermore, the air exchange device has a motor control for adjusting an engine power, wherein the engine control can be connected in particular to the evaluation unit, and at least one electric fan, which is connected to the engine control. In particular, the air exchange device may comprise an exhaust fan, a supply air fan and a heat exchanger. Exhaust air and supply air fans can be realized by the same fan or by separate fans.

The loudspeaker is connected to the evaluation unit, and arranged adjacent to an air flow, in particular on an air duct of the air exchange device. The air flow is generated by one of the electric fan of the air exchange device, which is located upstream of the speaker. The microphone is located adjacent to the airflow and downstream of the speaker. By this arrangement, a control loop can be realized in which the microphone measures the remaining noise that was not compensated by the loudspeaker.

According to the application, the evaluation unit may be configured to transmit the compensation signal when a noise suppression mode is activated, for example, due a microphone signal, due to the operation of a quiet switch, etc.

For efficient noise suppression, the loudspeaker may be located adjacent and downstream of one of the fans, that is adjacent to the supply air fan or adjacent to the exhaust fan.

Furthermore, for efficient noise suppression, the loudspeaker can be arranged on a wall of an air duct of the air exchange device, for example on a wall of an air supply duct or of an exhaust air duct. The speaker can also be mounted on the outside of a housing of the air exchange device.

The subject matter of the present application is described below with reference to an air exchange device with a separate supply and exhaust fan and with a cross-flow plate heat exchanger. However, it can also be realized in an air exchange device in which one and the same fan is used as Zuluft- and as exhaust fan, for example by periodic switching between supply and exhaust air operation. Furthermore, the object of the invention can also be realized in an air exchange device with a different type of recuperative heat exchanger, such as a countercurrent heat exchanger or a DC heat exchanger or in an air exchange device with a regenerative heat exchanger or a heat storage. In addition, the subject of the application can also be realized in an air exchange device without a heat exchanger.

The term air exchange device refers to systems which generate both a supply air flow and an exhaust air flow, wherein both the supply air and the exhaust air flow are passed through a designated area or through designated areas of the air exchange device.

An adaptation of a noise level according to the present application is particularly advantageous for decentralized air exchange devices in which the fan motors are arranged in a housing which is located in a room to be ventilated.

The subject matter of the application will now be described in more detail with reference to the following figures.

1 shows a schematic representation of a plan view of an air exchange device according to an embodiment,

2 shows a schematic representation of a cross section of an attached to an outer wall of a building air exchange device according to 1 , and

3 shows a schematic representation of a further cross section of the air exchange device according to 1 .

4 shows a plan view of a cover plate of the air exchange device with removed front housing part,

5 shows a schematic view of a fan motor controller with a microphone,

6 shows a state diagram of the fan motor controller,

7 shows a condenser microphone connected to the fan motor controller,

8th shows a flowchart of a first method for operating the air exchange device,

9 shows a flowchart of a second method for operating the air exchange device,

10 shows an air exchange device with an active noise suppression, and

11 shows a device for noise suppression with a speaker on an air duct.

The 1 - 3 show a schematic representation of a plan view of an air exchange device 1 according to an embodiment. The components of the air exchange device 1 are in the WO 03/081141 described here, wherein the same reference numerals are used. In this respect, WO 03/081141 is made in full part of the present description of the embodiment.

The terms "below" and "above" are used herein for description as in 1 is illustrated by the y-axis of a coordinate system. The terms "front" and "rear" are used herein in the direction of the z-axis. The terms "right" and "left" are used in the direction of the x-axis. Identical or similar components have the same reference numbers.

The air exchange device 1 is from a square case 3 enclosed. At the in 1 shown top view is the cover plate of the housing 3 decreased.

In the middle of the case 3 is a square plate heat exchanger 2 arranged, in particular of good heat-conducting material, wherein in the plan view according to 1 only the top plate of the plate heat exchanger 2 is visible.

Above the upper right side of the plate heat exchanger 2 is a cylindrical outside air round filter cartridge 5 essentially centered to the plate heat exchanger 2 arranged. When applying a cover plate, not shown here, to the housing 3 the bottom of the cover plate is located on the annular top of the outside air round filter cartridge 5 on. Inside the outside air round filter cartridge 5 is a circular outside air inlet 4 Visible, located on the bottom of the case 3 located.

To the outside air round filter cartridge 5 is one on the bottom of the case 3 placing, curved wall provided at the top and at the bottom of the right upper side of the plate heat exchanger 2 concludes. On the upper left side of the plate heat exchanger 2 a similarly shaped wall is provided at the top and at the bottom of the left upper side of the plate heat exchanger 2 concludes.

At the lower right side of the plate heat exchanger 2 is an exhaust fan housing 7 with a exhaust air radial fan 8th and one between the exhaust air radial fan 8th and the plate heat exchanger 2 arranged funnel 10 intended. On the entire width of the outlet side of the funnel 10 sets the exhaust air radial fan 8th from, in the plan view in 1 only the panel is recognizable. The axis of rotation of the exhaust air radial fan 8th is perpendicular to the height of the middle of the lower right side of the plate heat exchanger 2 aligned.

The exhaust air radial fan 8th is from an exhaust fan housing 7 enclosed on its underside a in 1 shown in broken lines, rectangular exhaust air outlet opening 9 having. This exhaust air outlet opening 9 is from the middle of the exhaust air fan 8th starting a bit offset to the top right.

At the lower left side of the plate heat exchanger 2 uses a thin-walled supply air fan housing 11 enclosed Zuluftansaugradiallüfter 12 at. The axis of rotation of the Zuluftansaugradiallüfters is 12 orthogonal to the lower left side of the plate heat exchanger 2 arranged at the height of their center. In the upper left area of the Zuluftansaugradiallüfters 12 is a rectangular Zulufteinlassöffnung 13 arranged through the multiple fan blades of Zuluftansaugradiallüfters 12 are recognizable.

A first section AA runs through the lower left and the upper right corner of the housing 3 , Another section line BB passes through the left upper and the lower right corner of the housing 3 ,

2 shows a schematic representation of a cross section along the section line AA one on an outer wall 15 attached air exchange device 1 according to the embodiment. In 2 is the heating side of the plate heat exchanger 2 considered.

The air exchange device 1 lies with the back of his case 3 at the front of the outer wall 15 and is therefore located inside the building. Here, the interior of the housing is divided 3 in an uppermost arranged outside air inlet area, in a centrally located plate heat exchanger area and in a lowermost Zuluftauslassbereich.

In the outside air intake area is at the rear of the housing 3 the outside air inlet opening 4 formed on the outside wall side, a horizontal outside air supply pipe 16 followed. The one with the back of the case 3 final area of the outdoor air round filter cartridge 5 delimits the outside air inlet opening 4 ,

In the plate heat exchanger area is the plate heat exchanger 2 arranged, the three parallel, in the illustration according to 3 From top to bottom extending air ducts. In the Zuluftauslassbereich is a supply air fan 14 within the supply fan housing 11 arranged. The supply fan 14 is arranged horizontally in the middle. At the same height as the fan blades of the supply fan 14 is in the front of the case 3 as well as in the left side of the supply air fan housing 11 a Zuluftauslassöffnung 13 provided, the amount of which corresponds to the width of the fan blades.

The supply air fan housing 11 put on the left as well as on the right end of the bottom of the plate heat exchanger 2 on, both sides vertically down and pointing directly in front of the bottom of the housing 3 a horizontal bottom on.

3 shows a schematic representation of a cross section along the section line BB of the outer wall 15 attached air exchange device 1 according to the embodiment. In 3 is the cooling side of the plate heat exchanger 2 considered.

The interior of the housing 3 is divided into an upper exhaust air inlet area 22 , in a medium plate heat exchanger area and in a lower exhaust air outlet area. In the exhaust air inlet area 22 is on the front of the case 3 an exhaust air inlet opening 17 provided by the exhaust air round filter cartridge 6 is delimited.

In the plate heat exchanger area is the plate heat exchanger 2 arranged, which has four parallel, vertically extending air ducts. The exhaust air outlet portion includes one in construction, in size, and in alignment with the in 3 shown Zuluftlüfterrad 14 identical exhaust fan 19 , The exhaust fan 19 is centered inside the exhaust fan housing 7 arranged. The supply air and exhaust air fans can be designed in various ways, for example as Zuluftansaug radial fan 12 and as exhaust air radial fan 8th , as in 1 to 3 shown, or as axial or as a cross-flow fan.

Horizontal at the same height as the exhaust fan 19 has the exhaust fan housing 7 on the right side as well as the case 3 on its back in each case an exhaust air outlet opening 9 on. At this exhaust air outlet opening 9 sets a exhaust air outlet pipe 20 which slopes slightly down to the right. Centered on the top of the exhaust fan housing 7 is an exhaust air supply opening 18 provided, whose width is about one third of the total width of the exhaust air fan housing 7 equivalent. Between the left and right ends of the bottom of the plate heat exchanger 2 and the left and right sides of the top of the exhaust air blower housing 7 is the funnel 10 arranged.

4 shows a plan view of the air exchange device 1 with removed housing cover. The air exchange device has a cover plate 21 on, on which a Zuluftführungskanal 25 with an intermediate wall 26 located. Furthermore, the view of 4 the exhaust air inlet opening 17 as well as a drive 22 for an exhaust air flap 23 and a supply air flap 24 ,

On a functional field 27 that on the cover plate 21 is arranged, are a digital display 28 and a microphone 29 arranged. Below the digital display 28 and the microphone 29 there is an evaluation unit 30 that with the digital display 28 , the microphone 29 , with the fan motors and with the damper drive 22 connected is.

Unlike in 4 shown, the microphone can also be arranged in a remote control for the air exchange device, wherein the remote control is arranged on a holder on the inner wall of a building. As a result, a separation of engine noise and external noise, which originate from the interior of the building, easier. Furthermore, the remote control allows convenient operation of the air exchange device.

The microphone 29 can be carried out in various ways, for example as a condenser microphone. In particular, the microphone can 29 be designed as a particularly energy-saving the electret condenser microphone in which an electret material generates an electric field of the capacitor, so that in contrast to a simple condenser microphone no Kapselvorspannung is required.

Furthermore, the microphone 29 also be embodied, for example, as an energy-saving MEMS microphone, in which the microphone 29 is designed as a microelectromechanical system. The capacitor of the MEMS microphone may be fabricated as part of a chip, such as an application specific integrated circuit (ASICS), using the usual chip fabrication techniques. Thus, the MEMS microphone offers the further advantage that the microphone 29 and the associated evaluation unit 30 as a compact integrated unit can be made. The training as an integrated unit, the digital signal processing of the microphone signals is simplified. Digital signal processing in the vicinity of the microphone can be used according to the application to improve noise suppression and immunity to interference.

The evaluation unit 30 is adapted to receive and evaluate signals from the microphone and to control the motors of the air exchange device on the basis of these received signals. For this the evaluation unit has 30 various modes of operation such as a exam mode, a voice control mode, a noise suppression mode, and a maintenance mode.

The evaluation unit 30 also has a device for filtering out engine noise emanating from the supply air fan and the exhaust fan. The filtering of the fan noise can be done, for example, by suppressing certain frequencies which occur as a function of a fan speed.

For this the evaluation unit selects 30 depending on the fan speed, a predetermined noise profile from a profile database and adjusts an adjustable digital or analog filter according to the noise profile. In the simplest case, the fan speed can be approximated above a set speed level. Furthermore, the fan speed can be measured via optical or magnetic speed sensors, for example via a Rückinduktion, which is determined while a power supply to a fan motor is temporarily interrupted.

According to another method, the evaluation unit selects 30 the predetermined noise profile based on a power that is supplied to the engine of the supply air fan or the exhaust fan. Furthermore, according to the application, a recognition of the fan noise can also be based on a temporal periodicity of the engine noise.

According to the application, it is also possible to use the noise profiles of the evaluation unit in a maintenance mode. If the noise profile of a fan motor does not correspond to a predefined noise profile at a certain speed or given a specific energy supply, then the evaluation unit determines whether an engine fault exists or if a filter has to be replaced and outputs a corresponding optical or acoustic signal.

According to the application, an exam mode becomes by operating a soft switch 38 triggered. Alternatively, the exam mode may also be triggered automatically by detecting a noise event in which an irregular noise caused, for example, by entering a exam room and taking seating, is followed by a relative decrease in the noise level for a predetermined minimum time becomes.

The noise level in the examination room is detected according to the registration by the microphone of the air exchange device. In an embodiment in which the microphone is arranged on the air exchange device, the noise in an interior space can be separated from the inherent noise of the fan motors by means of signal filtering. According to the application, the air exchange device 1 continue to have a timer.

When the exam mode is triggered, the air exchange device switches 1 into a state of rest. This hibernation may include low power operation or turning off the fan motors. The evaluation unit gives this 30 a signal to a controller to reduce the speed of the fan motors or completely turn off the fan motors. A control device stores the previously set speed level and controls the fan motors, for example via a pulse width modulation, so that the speed of the fan motors is reduced accordingly.

According to a specific embodiment, switching to the exam mode takes place depending on whether a room lighting is switched on. For this purpose, a photodiode 55 or a photosensor may be provided. The evaluation unit 30 evaluates the signal of the photodiode 55 and determines that the room lighting is on when the signal strength exceeds a threshold. The evaluation unit 30 can be set so that when you press the quiet switch 38 in each case in the exam mode or sleep mode is switched. This is advantageous, for example, when the photosensor is hidden or defective.

After a predetermined time, the air exchange device tests by evaluating the microphone signals, whether a renewed increase in the noise level occurs and the noise level for a predetermined minimum time is above a predetermined threshold. Then the exam mode is terminated and the speed of the fan motors is reset to the previously set speed. The evaluation of the microphone signals can be carried out in particular at temporal intervals and include an evaluation of the noise profile.

Furthermore, the evaluation unit 30 according to the application terminate the exam mode after a predetermined maximum period of time and reset the fan (s) after a maximum period of time back to the previous speed level. The timer can be used in conjunction with a clock to capture the scheduled duration of a test and to use in determining the quiet state. For example, the end or beginning of a scheduled exam date can be entered manually.

The noise detection can also be applied to other similar situations, for example, in courses with many participants. The use of a timer and a clock, in particular for conferences and other events may be advantageous in which the beginning and end of the event can not be so easily determined by acoustic characteristics. Furthermore, the switch to a quiet mode based on a predefined noise profile is also suitable for libraries, meditation rooms, theaters, concert halls and recording studios.

In a further embodiment, the evaluation unit 30 determine the presence of persons based on a noise level and the air exchange device 1 activate due to the presence of the persons. Such an embodiment is suitable, for example, for waiting areas, for toilets, for rooms that are reserved for smokers, for waiting rooms in medical practices and immediately. On the other hand, it may be advantageous in the treatment rooms of dental practices, the noise level in the presence of people, to avoid that patients are made nervous by fan noise.

The microphone 29 can in an according to the application air exchange device 1 continue to be used to detect a signal from a fire siren and the air exchange device 1 automatically switch to a fire alarm mode. Another application is to control an active speaker in anti-phase in a noise suppression mode, so that engine noise of the supply and exhaust fans are at least partially compensated.

In a command mode, a voice signal is identified which corresponds to a fan function and the corresponding fan function is switched on or off. This can also be done so that the corresponding commands must be repeated for checking. The display gives a visual feedback about which function was detected or whether no function was detected. The display can according to the registration a digital display 28 or, for example, an arrangement of a red, yellow and green LED, which is also clearly visible from a distance.

According to the application, a feedback can also be made by an acoustic signal. The acoustic signal can be output by a separate speaker, for example, on the function panel 27 is arranged. Alternatively, the evaluation unit 30 also the microphone 29 in a reverse mode as a loudspeaker drive.

A feedback can be output in a simple embodiment as a kind of optical or acoustic Morse signal. For example, a set power level can be represented by a corresponding number of audio signals or flashing signals. According to the application, further coding may be performed on the optical signals, for example by color and / or arrangement, and on the acoustic signals by pitch. Feedback on acoustic signals is especially beneficial for blind users.

The recognition features of the speech signals may be prior to delivery of the air exchange device 1 factory-stored in a memory or be assigned by means of a training mode the corresponding fan functions. The training of the speech signals can be done for example by means of a remote control. A user then selects in training mode with the remote control the function to be assigned to a command such as "Air on" or "Level three" and then speaks the associated command into the microphone. The evaluation unit 30 then extracts characteristic features from the voice command and associates them with the command. This assignment can be done in particular by means of a neural network.

Furthermore, the acoustic commands may also be generated, for example, by signals from an acoustic device, such as a whistle, a dog whistle, or a dial tone from a telephone keypad. The selection signal makes it possible, in particular, for the air exchange device 1 similar to an answering machine, to interrogate or remotely control by a signal from a telephone line.

By an acoustic command recognition according to the application, a user without a remote control with power supply can get along to the air exchange device 1 to remotely control. Such a situation may exist, for example, when the air exchange device is attached to a hard-to-reach location, such as the ceiling. On the other hand, speech control according to the application is also well suited for cases in which a user can not move himself, such as in a hospital bed, in a permanent movement restriction or in a blind user.

Other applications for voice control arise in situations where, for safety or other reasons, there may be temporarily no users in the vicinity of the air exchange device, but air exchange or air filtering is desired. The speech signals can in this case be generated by a loudspeaker.

5 shows a schematic diagram of a fan control with a microphone input according to the application.

An output line of the microphone 29 is with an evaluation unit 30 connected. The evaluation unit 30 is via a control line with a motor control 34 connected. The engine control 34 has a controllable power supply for the supply fan 12 and for the exhaust fan 8th on. The controllable power supply can be designed, for example, as pulse width modulation or as a phase control.

A display area 31 that the digital display 28 , a light-emitting diode 32 and a speaker 33 has with the evaluation unit 30 and with the engine control 34 connected. Furthermore, one is photodiode 55 with the display area 31 or with the evaluation unit 30 connected.

The evaluation unit is with operating elements 54 connected. Exemplary is in 5 a quiet switch 38 as well as a mode switch 39 shown. The quiet switch 38 is mounted in one embodiment at an easily accessible location of the fan housing. In another embodiment, it is attached to a remote control, which is mounted at a readily accessible height on a building wall and, for example, by radio or via an electrical line to the air exchange device 1 communicated.

In operation, the evaluation unit takes 30 acoustic signals or noises via the microphone 29 and sends in response to the received acoustic signals control signals to the engine control 34 and / or display signals to the display area 31 wherein the indication signals are from an operating state of the air exchange device 1 depend. Likewise sends also the engine control 34 Display signals, which indicate an operating state of the air exchange device 1 depend on the display area 31 ,

6 shows a state diagram of the fan control of 5 , In a switched off state 40 the air exchange device does not accept commands. By actuating a switch on the air exchange device 1 can the air exchange device 1 in a standard mode 41 be offset, in which an operating state of the air exchange device is determined by controls on the air exchange device.

From this standard mode 41 can the air exchange device 1 in the exam mode 42 , in the noise canceling mode 43 or in command mode 44 switch. This change can be for example from an acoustic signal through the microphone 29 or triggered by a timer signal. In the exam mode 42 , the noise suppression mode 43 and in the command mode 44 At least part of the operating state of the air exchange device is determined by acoustic signals emitted by the microphone 29 be received.

Conversely, the air exchange device may be of the command mode 44 back to the noise suppression mode 43 , in the exam mode 42 or in standard mode 41 switch. This change can for example be triggered by a command signal through the microphone 29 Will be received.

Furthermore, the air exchange device 1 For example, by spoken commands, between the command mode 44 and the training mode 45 switch back and forth. The change from training mode 45 to the command mode 44 can also be done automatically, if after a certain time no more to be learned commands are entered.

The command mode may include a standby mode in which the fans of the air exchange device are turned off, but in which the air exchange device may continue to receive and process an audible signal. In this way, it is not necessary to turn on the device by hand.

7 shows a wiring diagram for an electret microphone 48 that with the evaluation unit 30 connected is. The electret microphone 48 has a capacitor 49 with an electret material on. The capacitor 49 is with a base of a transistor 50 connected. The transistor 50 and the capacitor 49 are in a housing 51 arranged. A connection 52 of the transistor 50 is connected to a voltage source and via a capacitor 53 connected to the evaluation unit. Another connection of the transistor 50 is together with a connection of the capacitor 49 grounded.

The 8th and 9 show flowcharts of methods for switching to a sleep mode according to the application. After a switch-on step 56 changes the air exchange device in one step 57 in a normal mode with a preset power level. In a decision step 58 a check is made as to whether a signal for silent switching is received. This signal can be done for example via a quiet switch or by an electronic evaluation of a microphone signal.

If a signal for silent switching is received, then in one step 59 The speed or power consumption of one or more fan motors is reduced and this speed or power consumption is increased in one step 60 maintained for a given period of time. After the specified period of time, the external volume in step is at intervals 61 detected. In one step 62 it is checked whether a predetermined noise level is exceeded for a predetermined minimum period of time. If this is the case, then the normal operation in step 57 changed. If this is not the case, continue according to step 61 the outside volume is detected.

According to the method of 9 starts the air exchange device after switching on in step 63 in a reduced speed operation. In one step 64 At intervals the external volume is controlled by a microphone connected to the Air exchange device or attached to a remote control of the air exchange device detected.

In a decision step 65 is decided by an electronic evaluation unit, whether the external volume or the external noise exceeds a predetermined noise level. If this is not the case, then the external volume continues to be determined according to step 64 detected. If this is the case, it will be in one step 66 increases the speed or the performance of the fan motors or the. In a further step 67 the external volume is detected again. In accordance with a decision step 68 is set to operate at reduced speed according to step 63 switched back if the external volume does not exceed a predetermined value for a predetermined period of time and it is again the external volume according to step 67 detected when the external volume exceeds the predetermined value for the predetermined time, so in the operation at reduced speed in step 63 switched back.

10 shows an air exchange device 1 according to the application, a speaker 37 for noise compensation, in the supply air duct 25 is arranged near the supply air fan. The speaker 37 is with the evaluation unit 30 connected.

11 shows a device for noise suppression, wherein a speaker 37 and a microphone 29 ' in a supply air duct 25 adjacent to a supply air flow 69 are arranged. The microphone 29 ' is with respect to the supply air flow 69 downstream from the speaker 37 arranged. The microphone has microphone connections 70 . 71 on and the speaker has speaker connections 72 . 73 on. One or both of the microphone connections 70 . 71 and one or both of the speaker terminals 72 . 73 are with the evaluation unit not shown here 30 connected. Furthermore, the speaker points 37 including a movable membrane 74 , a holder 75 and a magnet 76 on.

For an active noise suppression according to the application, the evaluation unit receives 30 a microphone signal through the microphone connectors 70 . 71 of the microphone 29 ' calculated on the basis of this signal a compensation signal that is modulated so that air vibrations caused by the supply fan are suppressed, and sends this compensation signal to the speaker 37 , For example, the compensation signal may be modulated to be approximately proportional to the microphone signal but out of phase by approximately 180 degrees.

Instead of perpendicular to the flow direction, as in 11 shown, the speaker can 37 Also, be arranged at a different angle to the flow direction, for example, to suppress a noise that propagates at an angle to the flow direction and is reflected by the walls of an air duct back and forth.

In particular, the evaluation unit 30 be configured to transmit the compensation signal when a noise suppression mode is activated. The noise suppression mode can be switched on automatically if one of the conditions mentioned above is fulfilled, for example if a predefined noise level for a minimum time has been exceeded or if a quiet switch 38 was pressed.

An active noise cancellation via the loudspeaker 37 offers the advantage that the fan power of an air supply fan does not need to be reduced so much to adequately reduce the noise level of the supply air fan. The Noise Canceling mode only consumes power for active noise cancellation by the speaker when the noise cancellation mode is activated.

According to the application, a further microphone may be provided for better determination of the compensation signal, which is provided in the vicinity of the supply air fan, and that with the evaluation unit 30 connected is. This microphone is in 10 Not shown.

According to the application, a speaker for noise suppression also at other locations in Zuluftführungskanal 25 be provided as in 10 shown. Furthermore, a loudspeaker for noise suppression can also be arranged in an exhaust air duct or on an outside of the housing.

QUOTES INCLUDE IN THE DESCRIPTION

This list of the documents listed by the applicant has been generated automatically and is included solely for the better information of the reader. The list is not part of the German patent or utility model application. The DPMA assumes no liability for any errors or omissions.

Cited patent literature

• US 2010310083 [0004]
• US 2003/0161490 [0005]
• WO 03/081141 [0051]

Claims (18)

Air exchange device ( 1 ) with an acoustically controlled fan control, wherein the acoustically controlled fan control comprises: - a microphone ( 29 ), - one with the microphone ( 29 ) associated evaluation unit ( 30 ), which is set up to evaluate acoustic signals transmitted via the microphone ( 29 ) and converted into electrical signals, - a motor control ( 34 ) for adjusting an engine power, wherein the engine control ( 34 ) with the evaluation unit ( 30 ), - at least one electric fan ( 8th . 12 ), with the engine control ( 34 ), the evaluation unit ( 30 ) is adapted to the engine power of the at least one electric fan ( 8th . 12 ) when a predetermined noise level is exceeded for a predetermined minimum period of time. Air exchange device ( 1 ) with an acoustically controlled fan control, wherein the acoustically controlled fan control comprises: - a microphone ( 29 ), - one with the microphone ( 29 ) associated evaluation unit ( 30 ), which is set up to evaluate acoustic signals transmitted via the microphone ( 29 ) and converted into electrical signals, - a motor control ( 34 ) for adjusting an engine power, wherein the engine control ( 34 ) is connected to the evaluation unit, - at least one electric fan ( 8th . 12 ) with the engine control ( 34 ), the evaluation unit ( 30 ) is adapted to the engine power of the at least one electric fan ( 8th . 12 ), if a predetermined noise level is undershot for a predetermined minimum period of time. Air exchange device ( 1 ) according to claim 2, comprising a photosensor ( 55 ) connected to the evaluation unit ( 30 ), the evaluation unit ( 30 ) is adapted to the engine power of the at least one engine ( 8th . 12 ) to increase if the first condition falls below a predetermined brightness and if the second condition falls below a predetermined noise level for a predetermined minimum period. Air exchange device ( 1 ) according to claim 1, wherein the evaluation unit ( 30 ) is adapted to the engine power of the at least one fan ( 8th . 12 ), when a predetermined noise level is undershot for a predetermined minimum period of time. Air exchange device ( 1 ) according to claim 1 or claim 4, further comprising a quiet switch ( 38 ), wherein the evaluation unit ( 30 ) is adapted to the engine power of the at least one fan ( 8th . 12 ) when the quiet switch is pressed. Air exchange device ( 1 ) according to claim 1 or claim 4, which is a photosensor ( 55 ) connected to the evaluation unit ( 30 ), the evaluation unit ( 30 ) is adapted to the engine power of the at least one fan ( 8th . 12 ) to decrease when the first condition, a predetermined brightness is exceeded and when the second condition, a predetermined noise level for a predetermined minimum period is exceeded. Air exchange device ( 1 ) according to one of the preceding claims, comprising the following features: - a receiving device for receiving control signals, - a remote control which is set up, via the control signals with the evaluation unit ( 30 ), the remote control has a quiet switch ( 38 ), and wherein the remote control is adapted, in response to an actuation of the quiet switch ( 38 ) a control signal for reducing the fan power of the at least one fan ( 8th . 12 ) to the receiving device. Air exchange device ( 1 ) according to one of the preceding claims, comprising the following features: - a receiving device for receiving control signals, - a remote control, which is adapted to communicate via the control signals to the evaluation unit, wherein the remote control further comprises a microphone and a transmission device for transmitting Having detected with the microphone information. Air exchange device ( 1 ) according to one of the preceding claims, comprising means for setting the predetermined noise level. Air exchange device ( 1 ) according to one of the preceding claims, wherein the evaluation unit ( 30 ): - a device for selecting a predefined noise profile, - a device for determining a fan's own noise on the basis of the selected noise profile; A device for separating the electrical signal into the fan noise and an external noise and a device for evaluating a noise level of the external noise. Air exchange device ( 1 ) according to one of the preceding claims, wherein the engine control ( 34 ) comprises: a pulse width modulation and a device for adjusting a duty cycle of the pulse width modulation. Air exchange device ( 1 ) with an acoustically controlled error detection, wherein the acoustically controlled error detection comprises: a microphone ( 29 ), - one with the microphone ( 29 ) electrically connected evaluation unit ( 30 ), wherein the air exchange device ( 1 ) further comprises: - a motor controller ( 34 ) connected to the evaluation unit ( 30 ), - at least one fan ( 8th . 12 ), with the engine control ( 34 ), the evaluation unit ( 30 ) is set up for the evaluation of acoustic signals transmitted via the microphone ( 29 ) and converted into electrical signals, wherein the evaluation unit ( 30 ): - a device for determining a fan noise of the at least one fan ( 8th . 12 ) based on the electrical signal; A device for analyzing the fan self-noise and for generating an error signal on the basis of the fan self-noise, a device for outputting an error signal via a display region of the air exchange device, 1 ), if a predefined error condition is fulfilled. Air exchange device ( 1 ) according to one of the preceding claims, wherein the evaluation unit ( 30 ) of the air exchange device ( 1 ) comprises a computer readable memory having computer readable instructions for analyzing the microphone signal. Air exchange device ( 1 ) with an active noise suppression, wherein the air exchange device ( 1 ) has the following features: a microphone ( 29 ' ), - one with the microphone ( 29 ' ) associated evaluation unit ( 30 ), which is set up to evaluate acoustic signals transmitted via the microphone ( 29 ' ) and converted into electrical signals, - a motor control ( 34 ) for adjusting an engine power, - at least one electric fan ( 8th . 12 ) with the engine control ( 34 ), - a loudspeaker ( 37 ) for noise compensation, with the evaluation unit ( 30 ), and which is disposed adjacent to an airflow coming from the at least one electric fan ( 8th . 12 ) is generated, wherein the microphone ( 29 ' ) adjacent to the airflow and downstream of the loudspeaker ( 37 ), and wherein the evaluation unit ( 30 ) is adapted to provide a compensation signal for compensating engine noise to the loudspeaker ( 37 ) to send. Air exchange device ( 1 ) according to claim 14, wherein the evaluation unit ( 30 ) is adapted to transmit the compensation signal when a noise suppression mode is activated. Air exchange device ( 1 ) according to claim 14, wherein the loudspeaker ( 37 ) in an air supply duct ( 25 ) adjacent to a supply air fan ( 12 ) is attached. Air exchange device ( 1 ) according to claim 14, wherein the loudspeaker ( 37 ) adjacent to an exhaust fan ( 8th ) is attached. Air exchange device ( 1 ) according to claim 14, wherein the loudspeaker ( 37 ) on the outside of a housing of the air exchange device ( 1 ) is attached.

Images