DE102019101101A1 - Central ventilation unit with auxiliary room air extraction and ventilation processes for this - Google Patents

Abstract

A central ventilation system is described, which comprises: a ventilation device (2), which is designed for installation in a residential unit (32), an adjoining room connection (16), in which connections for a first and a second ancillary air duct (20, 22) are brought together are, an air conveying device (4) for exchanging air through an outer wall (3) of the residential unit (32) and for sucking in a collective exhaust air flow (26) from the adjoining room connection (16), and a control device (14) for actuating the air conveying device (4), whereby the ventilation system further comprises: a demand sensor (50) which emits a demand signal which indicates the need for conveying exhaust air from a second adjoining room, and an adjoining room ventilator (42) which is designed for connection to the end of the second adjoining room exhaust air duct (22) on the adjoining room side and has a control unit (48) connected to the demand sensor (50) for setting an air flow (30) conveyed by the fan (44), the S expensive device (48) switches the fan (44) between two operating stages, in which the fan (44) promotes a first or a second, higher volume flow into the second side room exhaust line (22), the control device (48) opening the fan (44) the first operating level sets when the demand signal indicates no or a basic requirement for the extraction of exhaust air from the second adjoining room (38), and switches to the second operating stage when the demand signal indicates an increased requirement for conveying exhaust air from the second adjoining room (38 ) indicates: the control device (14) of the ventilation device (2) controls the air delivery device (4) in such a way that it sucks in a volume flow (26) from the adjoining room connection (16) which is at least as large as a current volume flow (30) of the Fan (44) of the auxiliary room fan (42).

Description

The invention relates to a central ventilation system comprising: a ventilation device which is designed for installation in a residential unit, an adjoining room connection in which connections for a first and a second adjoining room exhaust air duct are combined, an air conveying device for exchanging air through the outer wall and for suction a collective exhaust air flow from the adjoining room connection, and a control device for controlling the air conveying device.

The invention further relates to a method for ventilating a building unit comprising a main room and a first and second secondary room, wherein a ventilation device is provided in the building unit, which has a secondary room connection in which a first and a second secondary room exhaust air duct are brought together, and an air delivery device for Has air exchange through the outer wall and for sucking a collective exhaust air flow from the adjoining room connection, and the first adjoining room exhaust air line is provided as a connection from the first adjoining room to the adjoining room connection and the second adjoining room exhaust air duct is provided as a connection from the second adjoining room to the adjoining room connection.

Better building insulation and more efficient heating systems mean that the energy requirements for building heating, particularly in the living area, are being reduced more and more. For various reasons, however, a minimum air exchange between the inside and outside of the building through the thermal building envelope, i.e. the outer wall, is absolutely necessary. The heat losses in such ventilation are therefore of considerable value, and ventilation devices with heat exchangers are used to reduce heat losses due to ventilation. Such ventilation devices are for example from the DE 102010042950 B4 or the DE 102010042948 A1 known. These are residential central ventilation units. Not only can they be installed easily, they also have the advantage that the occupant can control the ventilation unit themselves. The usual installation location is in the outer wall of a living room or bedroom, because the highest air quality is desired in these rooms. At the same time, other rooms in residential units must also be ventilated. Particular attention is paid here to damp rooms, such as bathrooms or toilets, or kitchen rooms, since such rooms often have no or insufficient natural ventilation via windows etc. A bathroom or toilet, for example, is often designed as a windowless room. The above-mentioned ventilation devices therefore have a so-called adjoining room connection, through which exhaust air can be extracted from adjoining rooms. This exhaust air is blown out of the ventilation unit on the outer wall as exhaust air. The types of air, such as exhaust air etc., are referred to here in accordance with DIN EN 13779 and DIN EN 12792. The term “volume flow” is used here to denote the actual value of a flow if a distinction from the flow in and of itself is indicated. For example, an exhaust air flow with different volume flows can be promoted.

Now, the need for extracting air from adjoining rooms is not always the same. For example, for bathrooms that do not have a window, higher volume flows of exhaust air to be extracted are prescribed than for windowless toilets. Depending on the situation, it may also be necessary to temporarily extract higher volume flows. In the known central apartment ventilation system, which has a ventilation device that extracts exhaust air from the adjoining room connection from two adjoining rooms, for example a bathroom and a toilet, it is therefore either not possible to consider the two adjoining rooms individually with regard to their need for extracting exhaust air, or complex and maintenance-intensive valves or volume adjustment directions are required so that the collective exhaust air flow sucked in by the ventilation unit in the adjoining room connection can be divided as needed between the two adjoining rooms.

Also known are fans, which are coupled to a light switch or a separate switch and are switched on when using a bathroom or toilet.

The invention is therefore based on the object of realizing a ventilation of the exhaust air adapted to the needs of the two adjoining rooms in a central apartment ventilation system or a central apartment ventilation method without the need for complex actuators in the ventilation system between the ventilation unit and the adjoining rooms.

The invention is characterized in the independent claims. The subclaims relate to preferred developments of the invention.

A central ventilation system has a ventilation unit. This is designed for installation in a building unit, for example a residential unit. It has an adjoining room connection, in which connections for at least a first or a second ancillary air duct can be brought together. An air conveying device provided in the ventilation unit, for example a blower, etc., promotes the exchange of air either directly through an outer wall into the open or first through a ceiling into which the ventilation unit is installed and from there into the open. It sucks in a collective exhaust air flow from the adjacent room connection. This collective exhaust air flow is made up of the individual Exhaust air flows together, which flow from the side room exhaust air ducts. The ventilation device also has a control device for controlling the air delivery device. In addition, a demand sensor is also provided, which emits a demand signal that indicates the need for conveying exhaust air from the second adjoining room, which can be, for example, a toilet or kitchen room.

The ventilation system has an auxiliary room fan for this second auxiliary room. It is shown in the second side room for connection to the end of the second side room exhaust air line and has a fan that promotes an exhaust air flow from the second side room into the second side room air exhaust line. It is preferably speed-controlled. The auxiliary room fan is also equipped with a control unit for setting an air flow conveyed by the fan. The control unit is connected to the demand sensor and switches the fan between at least two operating levels. In a first operating stage, the fan conveys a first volume flow into the second side room exhaust line; In a second operating stage, the delivery rate is higher and the fan delivers a second, higher volume flow, again into the second side room exhaust line. The control unit evaluates the demand signal from the demand sensor and switches the fan to the first operating level when the demand signal indicates no or only a basic requirement for the extraction of exhaust air from the second adjoining room. If the demand signal indicates an increased demand for extracting exhaust air from the second adjoining room, the control unit switches the fan to the second, higher operating level.

This ensures that exhaust air with different volume flows is drawn off from the second adjoining room as required. Furthermore, the control device of the ventilation device is designed in such a way that it adjusts its air delivery device in such a way that it sucks in a volume flow from the adjoining room connection which is at least as large as a current volume flow of the fan, which is part of the adjoining room fan. In this way it is ensured that an undesirable backflow of exhaust air, which was drawn off from the secondary room fan from the second secondary room and fed into the second secondary room exhaust line, is excluded via the secondary room connection into the first secondary room exhaust line. The air delivery device sucks in a volume flow from the adjoining room connection, which is dimensioned such that the volume flow which was fed into the second adjoining room exhaust air line by the adjoining room fan is completely removed.

For this property, the control device must have some knowledge of the volume flow that is fed by the fan of the auxiliary room fan into the second auxiliary room exhaust line. In a first variant, the current volume flow is reported to the control device via data communication between the auxiliary room fan and the ventilation unit. The control device of the ventilation device can take this into account and control the air delivery device accordingly. However, a second variant is preferred, in which there is no data connection between the control device of the ventilation device and the control device of the auxiliary room fan, since such data connections are generally complex, in particular if they are wired. Rather, the control device controls the air conveying device in such a way that the volume flow sucked in from the side room connection is at least as large as the second, higher volume flow that the fan of the side room fan can feed into the second side room exhaust air line. This ensures for both operating levels, which the control unit of the auxiliary room fan sets, that no backflow can take place from the auxiliary room connection into the first auxiliary room exhaust air line, since the air conveying device also sucks off the volume flow requested via the first auxiliary room exhaust air line in the second operating stage.

An example for values of the volume flows results from DIN regulations, which prescribe a basic volume flow of 15 m ³ / h for a windowless toilet. This is the first volume flow in the first operating stage. If necessary, ie when using the second adjoining room, eg the toilet, double the volume flow, ie 30 m ³ / h is required. This is the second volume flow. If the control unit sets the air delivery device of the ventilation unit to a minimum value for the collective exhaust air flow of 30 m ³ / h, regardless of the current operating level of the auxiliary room fan, it is ensured that all exhaust air from the second auxiliary room is extracted by the ventilation unit.

The side room fan at the end of the second side room exhaust air duct not only has the advantage that a demand-dependent exhaust air extraction from the second side room is possible, it also increases the ratio of the volume flows that can be conveyed through the side room exhaust air ducts to vary. Without an auxiliary room fan, the ratio of the volume flows that are extracted from the first and second auxiliary room would only be defined by the nominal cross-sections and line lengths of the first and second auxiliary room exhaust air ducts. A stronger operation of the air conveyor would not change this ratio. The auxiliary room fan can now not only be used to extract exhaust air from the second auxiliary room, it is also possible to influence the ratio of the volume flows with which exhaust air is extracted from the first and second auxiliary room.

If, for example, you use conventional secondary room exhaust air ducts, which as a rule have twice the nominal cross-section for the exhaust air from a bathroom, as an auxiliary room exhaust air duct to a toilet, the controlled operation of the auxiliary room fan in combination with the ventilation unit can still be a 1 in the basic state : 1 distribution of the volume flow extracted by the air delivery device from the adjoining room connection to the first and second adjoining room. Without the side room fan, the ratio would be about 2: 1. In order to implement the prescribed basic ventilation of, for example, 15 m ³ / h in the second adjoining room, the air delivery device would therefore have to extract, for example, 45 m ³ / h from the adjoining room connection. About 15 m ³ / h came from the second side room and about 30 m ³ / h from the first side room. This would be disadvantageous since only a volume flow of about 15 m ³ / h is required as the basic requirement for the first adjoining room according to the usual regulations. With such a division, not only would the energy requirement for the air conveying device be increased, but there would also be the risk that the first adjoining room would be dried out too much, since too much exhaust air is extracted. Due to the effect of the auxiliary room fan, the throughput through the second auxiliary room exhaust line is increased, for example to 15 m ³ / h. The volume flow from the first adjoining room drops because the air delivery device conveys a higher proportion of exhaust air from the second adjoining room exhaust air line due to the adjoining room fan. For the volume flow of 15 m ³ / h already mentioned by way of example, it now only has to extract 30 m ³ / h and yet the desired volume flow of 15 m ³ / h of exhaust air is extracted from both side rooms, although the nominal cross sections of the side room exhaust air ducts are different.

At the same time, an increased suction flow from the adjoining room connection only increases the exhaust air flow from the first adjoining room. This is technically expedient since, depending on requirements, a larger volume flow of exhaust air must be extracted from the first adjoining room than from the second adjoining room. Example values would be 75 m ³ / h of collective exhaust air flow, with 60 m ³ / h coming from the first adjoining room when the adjoining room fan is operating at the first operating level.

The suction requirement for the first adjoining room can be determined in different ways. Since the first adjoining room is usually a damp room, eg a bathroom, a moisture measurement is useful to determine the need for extracting exhaust air. For example, a humidity sensor can be provided in the first adjoining room to determine the need, which is then derived from a humidity signal. Another air quality signal can also be used, for example a CO ² or VOC measurement.

In order to save the data connection between the air quality sensor and the ventilation unit and thus to avoid installation and maintenance work, it is preferred to arrange the air quality sensor in such a way that it detects the collective exhaust air flow. In order to be able to determine the demand in the first adjoining room, the control device then intermittently stops the adjoining room fan independently of the signal from the demand sensor, and the control device reads out the air quality sensor in the meantime. If the auxiliary room fan does not deliver any additional exhaust air to the second auxiliary room exhaust air duct, the conduction-related ratio is established in the collective exhaust air flow. Due to the associated change in the signal of the air quality sensor, the control device can easily determine the value of the corresponding air quality parameter in the exhaust air from the first adjoining room. This is particularly easy in the case of a humidity sensor, since the humidity rises sharply when a bath is used, so that the need can be easily recognized. The intermittent stopping of the fan in the second adjoining room is either provided at predetermined times or the control device is configured such that it detects the standstill of the fan. There are various options for this. For example, the control device can evaluate the signal of the air quality sensor and detect a stop in the adjoining room fan when there is a signal jump. It is also possible to provide a pressure sensor current in the adjoining room connection, by means of which the standstill of the adjoining room fan is recognized. An acoustic detection of the running noise of the fan of the auxiliary room fan is also possible, for example by means of a corresponding sensor in the auxiliary room connection. Finally, it is also possible for the control device of the auxiliary room fan to indicate the standstill of the fan to the control device of the ventilation device.

In some embodiments, the air quality sensor detects the collective exhaust air flow without the control device having to stop the auxiliary room fan intermittently. The signal change from which a need for conveying exhaust air from the first adjoining room is determined is then less, since, for example, only a portion, for example half, of the collective exhaust air flow comes from the first adjoining room when the fan is operating in the second operating stage. however, a signal jump can still be sufficient to detect a use of the first adjoining room and thus a need for conveying exhaust air. With the air humidity measurement already mentioned, this is easy, for example, since the air humidity in the bathroom increases very strongly when showering or bathing.

The demand sensor in the second adjoining room can be a VOC sensor, particularly if the second adjoining room is a toilet. It can also be an ambient brightness sensor, since in a windowless second adjoining room the room lighting is switched on regularly during use. Also a motion sensor, e.g. B. an IR sensor is possible.

In the two operating stages of the fan, a certain volume flow is generally desired, for example about 15 m ³ / h in the first operating stage and 30 m ³ / h in the second operating stage. In order to achieve this, it is preferred that the fan can be configured with regard to the operating stages to adapt to a flow resistance of the second auxiliary room exhaust line. This makes it possible in particular to set the first volume flow, which is conveyed in the first operating stage, essentially to half the exhaust air volume flow sucked in by the air delivery device in the basic state from the adjoining room connection. The configuration can take place, for example, by means of so-called DIP switches.

Insofar as properties of the ventilation system and its control device or the control device of the secondary fan have been described above, this naturally also applies equally to a method for ventilation of a residential unit which comprises a main room and a first and second secondary room. The ventilation device described is provided in an outer wall of the residential unit, which has the adjoining adjoining room connection, in which a first and a second adjoining room exhaust air duct are brought together. The air delivery device of the ventilation device is also designed here for air exchange through the outer wall and for drawing in a collective exhaust air flow from the adjacent room connection. The first secondary room exhaust line leads to a first secondary room, the second secondary room exhaust line leads to the second secondary room. At the end of the second side room exhaust air line, the mentioned side room fan is connected, which has the two operating stages mentioned, in which the fan promotes a first (lower) and a second (higher) volume flow into the second side room exhaust air. Depending on the needs for the extraction of exhaust air from the second adjoining room, the fan is set to the first or second operating level. At the same time, a volume flow that is at least as large as a current volume flow of the fan is sucked in from the adjoining room connection.

The alternatives mentioned at the beginning for adjusting the air delivery device are of course equally given in the method.

There is also an auxiliary room fan for the ventilation system mentioned, which is designed for connection to a room-side end of an exhaust air duct for a windowless toilet or a windowless kitchen room. It includes the fan mentioned for conveying exhaust air into the exhaust air line and a control unit that switches the fan between two operating levels. In the first operating stage, the already mentioned first (lower) volume flow is conveyed into the exhaust air line in the second operating stage, the second (higher) volume flow. The side room fan has the demand sensor mentioned in the form of a VOC and / or ambient brightness sensor. The control unit switches the fan to the first operating level when the sensor shows no or a basic requirement for the extraction of exhaust air from the toilet or kitchen room. If an increased demand is indicated by the VOC and / or ambient brightness sensor, the control unit switches the fan to the second operating level.

It goes without saying that the features mentioned above and those yet to be explained below can be used not only in the specified combinations but also in other combinations or on their own without departing from the scope of the present invention.

• 1 schematisch ein wohnungszentrales Lüftungsgerät, das in einer Außenwand einer Wohnung eingebaut ist, um Luft zwischen dem Wohnungsinneren und dem Wohnungsäußeren auszutauschen, und
• 2 eine Schemadarstellung einer Wohnung mit einem Wohnzimmer, einem Bad und einem WC, wobei im Wohnzimmer das wohnungszentrale Lüftungsgerät der 1 angeordnet ist und über Nebenraumabluftleitungen Abluft aus Bad und WC abgesaugt wird.

The invention is explained in more detail below on the basis of exemplary embodiments with reference to the accompanying drawings, which likewise disclose features essential to the invention. These exemplary embodiments are only illustrative and are not to be interpreted as restrictive. For example, a description of an exemplary embodiment with a large number of elements or components should not be interpreted to mean that all of these elements or components are necessary for implementation. Rather, other exemplary embodiments can also contain alternative elements and components, fewer elements or components or additional elements or components. Elements or components of different execution examples can be combined with one another, unless stated otherwise. Modifications and modifications, which are described for one of the exemplary embodiments, can also be applicable to other exemplary embodiments. To avoid repetitions, the same or corresponding elements in different figures are given the same reference numerals and are not explained several times. From the figures show:

• 1 schematically a central ventilation unit, which is installed in an outer wall of an apartment to exchange air between the interior and exterior of the apartment, and
• 2nd a schematic representation of an apartment with a living room, a bathroom and a toilet, with the central ventilation unit in the living room 1 is arranged and exhaust air from the bathroom and toilet is extracted via side room exhaust air ducts.

1 shows schematically a ventilation device 2nd , which is part of a central apartment ventilation system. The ventilation unit 2nd is in an outer wall 3rd a building unit, for example an apartment, installed and has a fan 4th that the air exchange between interior 6 and outside space 8th , i.e. from the interior of the apartment to the outside or vice versa. The ventilation unit 2nd can also be installed in a ceiling from where air lines lead to the outside. The following is purely exemplary of the outer wall 3rd spoken. In this regard, the ventilation unit 2nd designed in the manner as described in the German patent publications mentioned above. The ventilation unit 2nd often has a heat exchanger to cool the exhaust air and warm up the fresh air and thus to carry out heat recovery from the exhaust air. The in 1 The arrow shown concerns only the blowing out of exhaust air as exhaust air on the outside of the outer wall 3rd and is purely exemplary in this regard. The fan promotes the extraction of exhaust air 4th of the ventilation unit 2nd Air from an inside opening 10th to an outside opening 12th , in again 1 illustrated arrow illustrates. This is done under the control of a control device 14 that the operation of the fan 4th controls accordingly.

Except for the inside opening 10th can the ventilation unit 2nd (usually adjustable) also exhaust air from an adjoining room connection 16 aspirate that in a mixing chamber 18th ends in which a first side room exhaust duct 20 and a second side room exhaust duct 22 flow out. In the adjacent room connection 16 is also an air quality sensor, for example a moisture sensor 24th provided by the control device 14 is read out. It records the air quality, for example the humidity of a collective exhaust air flow 26 which, when operated appropriately, by the fan 4th is sucked in.

The collective exhaust air flow 26 is made up of two parts, namely the exhaust air flows from the two side room exhaust air ducts 20 , 22 stream in. The first side room exhaust duct 20 ends in a bathroom and is therefore also referred to below as the bathroom exhaust air duct. The second side room exhaust duct 22 ends in a toilet and is therefore referred to below as the toilet exhaust pipe. However, the assignments of the secondary room exhaust air ducts are not limited to this; other types of secondary rooms can also be connected. As an example, however, reference is made below to the bathroom and toilet. The exhaust air in the bathroom exhaust line 20 is a bath exhaust air flow 28 , the one in the toilet exhaust pipe 22 a toilet exhaust air flow. Both of you will be in the mixing chamber 18th mixed and form the collective exhaust air flow from there 26 .

The ventilation unit 2nd in the installation situation in an apartment 32 is in 2nd shown. It is in the outer wall 3rd . The details of the ventilation unit 2nd are in 2nd not shown. However, the bathroom exhaust air duct can be seen 20 and the toilet exhaust pipe 22 . The ventilation unit sits 2nd in an outer wall 3rd a living space, for example a living room 34 or a bedroom, is the end of the bathroom exhaust pipe 20 in a bath 36 and the toilet exhaust pipe 22 in a toilet 38 .

In the bathroom 36 the bathroom exhaust pipe ends 20 with a suction opening 40 through which the bath exhaust air flow 28 entry. Next is in 2nd optionally an alternative or additional moisture sensor 24 ' marked (only dashed), the one with the control device 14 is connected (eg by radio) to the need for extracting exhaust air from the bathroom 36 to be able to determine, as already explained in the general part of the description.

At the end of the bathroom exhaust pipe 22 there is a side room fan 42 who has a fan 44 has, which through a suction opening 46 Exhaust air from the toilet 38 sucked in and as a toilet exhaust air flow 30th into the toilet exhaust pipe 22 to the ventilation unit 2nd promotes. The side room fan 42 also has a control unit 48 and a demand sensor, which is exemplary as a VOC sensor 50 or can be designed as an ambient brightness sensor. The control unit uses this sensor to determine 40 whether there is an increased need to convey exhaust air from the toilet 38 is required. When designing the demand sensor as a VOC sensor 50 odors are detected, when configured as an ambient brightness sensor, switching on room lighting, which also indicates the use of the windowless toilet. The control unit switches if there is no increased demand for exhaust air through the demand sensor 48 the fan 44 in a basic stage in which, for example, 15 m ³ / h through the suction opening 46 is sucked in. If an increased demand is recognized, the volume flow is increased, for example doubled.

Because the bathroom exhaust pipe 20 and the toilet exhaust pipe 22 in the mixing chamber 18th (or elsewhere) in the adjacent room connection 16 are brought together, the control device ensures 14 making sure that the fan 4th from the adjacent room connection 16 a collective exhaust air flow 26 sucks in, whose volume flow is as large as the delivery rate of the fan 44 in the second stage of operation. In this way there is a return flow of exhaust air from the toilet 38 in the bathroom 36 locked out. For example, sucks the fan 4th , as already explained in the general part of the description, the collective exhaust air flow 26 with a volume flow of 30 m ³ / h. The fan is running 44 in the first stage of operation, the result is a volume flow of 15 m ³ / h both from the bathroom 36 as well as from the toilet 38 aspirated.

To meet an increased need to extract exhaust air from the bathroom 36 The air quality sensor can be recognized 24th or alternatively 24 'is provided, which can be designed, for example, as a moisture sensor, as mentioned. Based on its signal, there is an increased humidity in the collective exhaust air flow 26 recognized and the delivery rate of the fan 4th increased accordingly so that the bath exhaust air flow 28 increases accordingly. When the moisture sensor is arranged 24 ' in the bathroom 26 the moisture in the bathroom results immediately. When using the installation effort or data communication effort avoiding humidity sensor 24th in the ventilation unit 2nd receives the control device 14 a signal about the humidity of the collective exhaust air flow 26 . As already explained in the general part of the description, this signal is sufficient to prevent moisture in the bathroom 36 to recognize. Alternatively or additionally, the measures explained in the general part of the description can be considered, ie the intermittent stopping of the fan 44 .

Switches the control device 14 the fan 4th to a higher operating level in order to increase the exhaust air extraction requirement in the bathroom 36 the fan is preferred 44 into the toilet exhaust pipe 22 injected exhaust air flow is not increased, because in a preferred embodiment of the fan 44 is speed-controlled, that is, largely independently of the pressure, supplies the first or second volume flow in the first or second operating stage.

So far, a first and a second operating level for the side room fan 42 operation was of course not restricted to this. For example, it is possible to provide a "zero" operating level in which the fan 44 is switched off. A finer gradation with several different volume flows is also possible. To meet the current regulations, however, the first and the second operating level are preferably sufficient (and optionally an additional shutdown of the fan as the "zero" operating level ”).

The control unit 48 is adjustable with regard to the speed of the fan 44 in the first and second operating stages, so that an adaptation to the flow resistance of the toilet exhaust air duct can take place and still the desired first volume flow (e.g. 15 m ³ / h) and second volume flow (e.g. 30 m ³ / h ) are realized.

QUOTES INCLUDE IN THE DESCRIPTION

This list of documents listed by the applicant has been generated automatically and is only included 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.

Patent literature cited

• DE 102010042950 B4 [0003]
• DE 102010042948 A1 [0003]

Claims (17)

Central ventilation system, comprising - a ventilation device (2) which is designed for installation in a residential unit (32), an adjoining room connection (16) in which connections for a first and a second adjoining room exhaust air duct (20, 22) are brought together, and an air conveying device (4) for air exchange through an outer wall (3) of the residential unit (32) and for sucking in a collective exhaust air flow (26) from the adjoining room connection (16), and a control device (14) for controlling the air conveying device (4), characterized in that the Ventilation system further comprises - a demand sensor (50) which emits a demand signal indicating the need for conveying exhaust air from a second adjoining room, and - an adjoining room ventilator (42) which is designed for connection to the end of the second adjoining room exhaust air duct (22) on the adjoining room side and has a control unit (48) connected to the demand sensor (50) for setting an air flow (30) conveyed by the fan (44) - whereby the control unit (48) switches the fan (44) between two operating stages, in which the fan (44) delivers a first or a second, higher volume flow into the second side room exhaust air line (22), the control unit (48) the fan (44) to the first operating level if the demand signal indicates no or a basic requirement for the extraction of exhaust air from the second adjoining room (38), and to the second operating stage if the demand signal indicates an increased requirement for conveying exhaust air from the second adjoining room ( 38), - the control device (14) of the ventilation device (2) controls the air delivery device (4) in such a way that it draws in a volume flow (26) from the adjoining room connection (16) which is at least as large as a current volume flow (30 ) of the fan (44) of the auxiliary room fan (42). Ventilation system after Claim 1 , characterized in that the control device (14) of the ventilation device (2) has no data connection to the control device (48) of the auxiliary room fan (42) and controls the air delivery device (4) in such a way that it generates a volume flow (26) from the auxiliary room connection (16) sucked in, which is at least as large as the second volume flow of the fan (44). Ventilation system after Claim 1 or 2nd , characterized by a humidity sensor (24, 24 '), the control device (14) of the ventilation device (2) controlling the air conveying device (4) for drawing in the collective exhaust air flow (26) with a volume flow to determine the air humidity in the first adjoining room (36), which is at least as large as the current volume flow of the fan (44) plus a volume flow derived from the air humidity, which is related to the first adjoining room (36). Ventilation system according to one of the above claims, characterized in that - the ventilation device (2) has an air quality sensor (24) detecting the collective exhaust air flow (26), - the control device (48) intermittently the fan (44) regardless of the signal of the demand sensor (50) stops and - the control device (14) of the ventilation device (2) reads out the air quality sensor (24) in order to determine the need for conveying exhaust air from the first adjoining room (36), - the air quality sensor preferably being an air humidity sensor. Ventilation system according to one of the above claims, characterized in that the demand sensor (50) is a VOC sensor or an ambient brightness sensor or a motion sensor and is arranged in or on the side room fan (42). Ventilation system according to one of the above claims, characterized in that it comprises the first and the second auxiliary room exhaust line (20, 22), the first auxiliary room exhaust line (22) ending in a bath (36) and having a higher nominal cross section than the second auxiliary room exhaust line ( 22), which ends in a toilet (38) or a kitchen room. Ventilation system according to one of the preceding claims, characterized in that the operating stages of the fan (44) can be configured to adapt to a flow resistance of the second side room exhaust air line (22) in order to substantially reduce the first volume flow of the first operating stage to half that of the air conveying device (4 ) of the exhaust air volume flow drawn in from the adjacent room connection (16). Ventilation system according to one of the above claims, characterized in that the control device (14) of the ventilation device (2) and the control device (48) of the auxiliary room fan (42) are designed to set up a data communication connection and are further configured via the data communication connection to convey the output of fans (44) and air conveyor (4). Method for ventilating a residential unit (32) comprising a main room (34) and a first and second secondary room (36, 38), wherein - a ventilation device (2) is provided in a residential unit (32), which has a secondary room connection (16), in which a first and a second auxiliary room exhaust line (20, 22) are brought together, and an air delivery device (4) for air exchange through the outer wall (3) of the residential unit (32) and Sucking in a collective exhaust air flow (26) from the adjoining room connection (16), and - the first adjoining room exhaust air duct (20) as a connection from the first adjoining room (36) to the adjoining room connection (16) and the second adjoining room exhaust air duct (22) as a connection from the second adjoining room (38 ) to the adjoining room connection (16), characterized in that - an adjoining room ventilator (42) is connected to the adjoining room end of the second adjoining room exhaust air duct (22), which has two operating stages, in which a fan (44) of the adjoining room ventilator (42) has one promotes the first or a second, higher volume flow into the second side room exhaust air line (22), - the fan (44) is set to the first operating level if there is no or a basic requirement for the delivery of exhaust air from the second side room (38), the Fan (44) is set to the second operating level when there is an increased need for conveying exhaust air from the second adjoining room (38) - with the air conveying device (4) from the adjoining room connection (16) is sucked in a volume flow which is at least as large as a current volume flow of the fan (44). Procedure according to Claim 9 , characterized in that the air delivery device (4) draws in a volume flow from the adjoining room connection (16) which is at least as large as the volume flow of the fan (44) in the second operating stage. Procedure according to Claim 9 or 10th , characterized in that a need for the delivery of exhaust air from the first adjoining room (36) is determined and the air delivery device (4) draws in a volume flow from the adjoining room connection (16) which is at least as large as the current volume flow of the Fan (44) plus an additional volume flow, which depends on the need for conveying exhaust air from the first adjoining room (36). Procedure according to Claim 11 , characterized in that, in order to determine the need for conveying exhaust air from the first adjoining room (36), the fan (44) is stopped intermittently, independently of the need for conveying exhaust air from the second adjoining room, and an air quality, preferably humidity, of the collective exhaust air flow ( 26) is measured. Procedure according to one of the Claims 9 to 12th , characterized in that a VOC or an ambient brightness measurement is carried out to determine the need for conveying exhaust air from the second adjoining room (38). Procedure according to one of the Claims 9 to 13 , characterized in that the first secondary room exhaust line (20) ends in a bathroom (36) and has a higher nominal cross section than the second secondary room exhaust line (22) which ends in a toilet (38) or a kitchen room. Procedure according to one of the Claims 9 to 14 , characterized in that the operating stages of the fan (44) are adapted to a flow resistance of the second auxiliary room exhaust line (22), the first volume flow in the first operating stage being substantially equal to half that of the auxiliary room connection (16) from the air delivery device (4) aspirated volume flow is set. Procedure according to one of the Claims 9 to 15 , characterized in that a data communication connection is established between the ventilation device (2) and the auxiliary room fan (42), via which the delivery rates of the fan (44) and the air delivery device (4) are coordinated. Side room fan for a ventilation system according to one of the Claims 1 to 9 , which is designed for connection to a room-side end of an exhaust air duct (22) for a windowless toilet (38) or a windowless kitchen space, a fan (44) for conveying exhaust air into the exhaust air duct (22) and a control unit (48) for switching between two operating stages, in which the fan (44) delivers a first or a second, higher volume flow into the exhaust air line (22), the auxiliary room fan (42) having a VOC and / or an ambient brightness sensor and the control unit (48 ) switches the fan (44) to the first operating level when the VOC (50) and / or ambient brightness sensor shows no or a basic requirement for the extraction of exhaust air from the toilet (38) or kitchen area, and the fan (44) in the second operating level switches when the VOC (50) and / or an ambient brightness sensor indicates an increased need for the extraction of exhaust air from the toilet (38) or kitchen room.

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