DE102021004422A1 - Method for operating a ventilation system for ventilating a room, control device set up to carry out such a method, ventilation system with such a control device and vehicle with such a ventilation system - Google Patents

Abstract

The invention relates to a method for operating a ventilation system (5) for ventilating a room, in particular a vehicle cabin, a first spatial position (17) of at least one odor receiver (19) being detected, a second spatial position (25) of at least one odor source ( 27) of an odor is detected, an odor intensity of the odor being determined, the determined odor intensity being compared with a predetermined odor intensity threshold value, a suction device (29) and a suction device (31) being switched to a first active mode when the determined odor intensity is exceeds a predetermined odor intensity threshold value, the suction device (29) and the suction device (31) being controlled in the first active mode in such a way that the air flow generated by the suction device (29) and the suction device (31) absorbs the odor from the at least one odor receiver (19 ) w glides.

Description

The invention relates to a method for operating a ventilation system for ventilating a room, a control device set up to carry out such a method, a ventilation system with such a control device, and a vehicle with such a ventilation system.

In the case of methods for operating a ventilation system for ventilating a room, this mostly focuses exclusively on the thermal comfort of the user. Air that is too cold can be heated using a heater or air that is too warm can be cooled using an air conditioning system and then fed into the room in order to ensure the well-being of the user. However, the well-being of the user does not only depend on the temperature of the air supplied. Smell perception, i.e. the perception of smells, also has a very strong influence on the well-being of the user. Odors such as outgassing, sweat odor, bad breath or foot odor can lead to a reduced well-being of the user. It is desirable that users do not perceive the disruptive odors or only perceive them to a limited extent. In particular in motor vehicles, such as cars or buses, unpleasant smells can severely limit the well-being of users due to the closed space and the limited space available. It is known to mask bad smells in a vehicle cabin by the smell of a scented tree. There are also other known ways of masking the odor in a vehicle cabin. For example, a scenting system is used in the Mercedes S-Class, which scents the air contained in the vehicle cabin. The user can choose from a number of smells. In this process, however, the unpleasant odor is not removed, but also merely masked. the end US 2011/0319004 A1 a suction device is known, which is arranged in the seat of a seat and sucks off unpleasant odors in the event of outgassing. the end US 8083575 B2 a similar suction device is known, which is also arranged directly in the seat. These suction systems have the disadvantage that they have to be located very close to the source of the odor in terms of location so that the unpleasant odor does not reach a user. These extractors are only optimized to the effect that they suck off an odor in the area of the seat. Other odors such as sweat odor, bad breath or foot odor are not extracted efficiently.

The invention is therefore based on the object of creating a method for operating a ventilation system for ventilating a room, a control device set up to carry out such a method, a ventilation system with such a control device, and a vehicle with such a ventilation system, the disadvantages mentioned are reduced, preferably not occurring.

The object is achieved in that the present technical teaching is provided, in particular the teaching of the independent claims and of the preferred embodiments disclosed in the dependent claims and the description.

The object is achieved in particular by creating a method for operating a ventilation system for ventilating a room, in particular a vehicle cabin. A first spatial position of at least one odor receiver is detected, and a second spatial position of at least one odor source of an odor is detected. An odor intensity of the odor is determined, the determined odor intensity being compared with a predetermined odor intensity threshold value. A suction device and a suction device are switched to a first active mode when the determined odor intensity exceeds the predetermined odor intensity threshold value. The suction device and the suction device are controlled in the first active mode in such a way that the air flow generated by the suction device and the suction device guides the odor away from the at least one odor receptor. In this way, bad smells are advantageously kept away from the at least one odor receiver, preferably from all users of a room in their capacity as odor receiver.

In particular, an odor receiver is any receiver, in particular user, within the room who receives a potentially disruptive odor from an odor source. In particular, odor receivers are people who themselves do not emit an annoying odor, but receive an annoying odor from a source of odor. But it is also possible that a person is an odor recipient and at the same time an odor source.

In particular, the spatial position of an odor receiver is the position of a person who receives the odor. In particular, the spatial position of an odor receiver is also the position of a person's nose, in particular the head area of the person who receives the odor.

In particular, an odor source is any source within the room that generates, in particular emits, at least one odor that can be perceived as potentially disruptive by an odor recipient. In particular, a source of odor is a person or an object. In particular, a person emits an annoying odor if, for example, he has bad breath, suffers from outgassing, has applied too strong perfume, has smelly feet or smells of sweat. In particular, an object with an unpleasant smell is sweaty clothing, smelly shoes, food with strongly smelling ingredients, in particular onion or garlic. In particular, an odor source is also an animal, in particular a wet or dirty animal.

In particular, a first person who smells of sweat is a source of odor, the first person also being the odor recipient at the same time, since this person also receives the self-generated and potentially disruptive odor. In particular, as an alternative or in addition, at least one other person can also be an odor source, so that at least two odor sources, which are also odor receivers at the same time, may be present. In particular, a plurality of people can each be an odor source and odor recipient at the same time. In particular, each odor generated by an odor source that can be perceived as potentially disruptive by at least one odor recipient should then be diverted away from all odor recipients.

In particular, the suction device and the suction device are controlled in the first active mode in such a way that the odors generated by the at least one odor source do not reach the at least one odor receiver.

In particular, a suction device is a device that supplies air into the room. In particular, a suction device is a device that removes air from the room. In particular, air supplied to the room is fresh air from outside the room. Alternatively, however, the air supplied can also be from within the room, in particular in that the suction device removes air from the room and the suction device feeds it back into the room.

According to a development of the invention it is provided that the air flow is controlled in such a way that the air flow flows from the suction device to the at least one odor receiver, then to the at least one odor source, and then to the suction device. In this way, it is particularly advantageously ensured that the well-being of the at least one user is not impaired by bad smells.

According to a development of the invention it is provided that a body temperature of at least one user is recorded. The detected body temperature is compared with a predetermined body temperature threshold value, the suction device and the suction device being switched to a second active mode if the detected body temperature exceeds the predetermined body temperature threshold value. The suction device and the suction device are controlled in the second active mode in such a way that the air flow generated by the suction device and the suction device directs aerosols generated by the at least one sick user away from other users. In this way, aerosols contaminated with pathogens are advantageously kept away from all users of a room.

In particular, the suction device and the suction device are operated locally, that is to say for a partial area of the room, in the first active mode or in the second active mode. It is also possible that there are at least two partial areas within the room, the suction device and the suction device being operated in the first active mode or in the second active mode in each partial area. In particular, it is possible for there to be a plurality of partial areas within the room. Each seat within the room preferably forms its own sub-area, the suction device and the suction device being operated in the first active mode or in the second active mode in each sub-area.

In particular, it is also possible for the suction device and the suction device in the first sub-area to be operated in the first active mode, the suction device and the suction device being operated in the second active mode in a further sub-area different from the first sub-area. In particular, it is also possible that there are a plurality of sub-areas within the room, preferably each seat within the room forms its own sub-area, with the suction device and the suction device being operated in the first active mode in a first part of the sub-areas, whereas preferably in parallel , that is to say at the same time, the suction device and the suction device are operated in the second active mode in a second part of the subregions.

In particular, the suction device and the suction device are operated in a fresh air mode or in a circulating air mode. In particular, in fresh air mode, fresh air is sucked in from outside the room and supplied to the room, preferably through the suction device, with air being sucked out of the room at the same time, preferably by the suction device. In particular, in recirculation mode, air is sucked in from within the room - preferably by the suction device - and fed back into the room - preferably by the suction device. In particular, the air extracted from within the room is first passed through a filter device in which it is cleaned of odors and aerosols and then fed back into the room. In particular, it is also possible that fresh air is first cleaned of odors and aerosols before it is fed into the room. In particular, fresh air is only cleaned of odors or aerosols if the fresh air exceeds a predetermined odor threshold or a predetermined particle content threshold.

According to a further development of the invention it is provided that the suction device and the suction device are operated in a rest mode when the determined odor intensity falls below the predetermined odor intensity threshold value. As an alternative or in addition, it is provided that the suction device and the suction device are operated in a rest mode when the detected body temperature falls below the predetermined body temperature threshold value. The suction device and the suction device preferably convey less air in the rest mode than in the first active mode and in the second active mode. In particular, the suction device and the suction device are advantageously operated in the idle mode when there are no sick users in the room and there are no unpleasant smells in the room.

In particular, the suction device and the suction device are switched from a sleep mode directly to the first or second active mode. It is also possible for the suction device and the suction device to be switched from the first active mode to the second active mode, or from the second active mode to the first active mode. It is also possible for the suction device and the suction device to be switched from the first active mode first to the sleep mode and then to the second active mode, or from the second active mode to the sleep mode and then to the first active mode.

The object is also achieved by creating a control device which is set up to carry out a method according to the invention or a method according to one or more of the embodiments described above. In connection with the control device, there are in particular the advantages that have already been explained in connection with the method.

In particular, the control device can be arranged within a property in order to control the ventilation system of an entire property, but at least the ventilation system for a room in the property. Alternatively, the control device can also be arranged outside the property, preferably in a control room or on a server in a cloud.

In particular, the control device can be arranged within a room in order to control the ventilation system of a room. Alternatively, the control device can also be arranged outside the room, preferably in a control room different from the room to be ventilated or on a server in a cloud.

In particular, the control device can be arranged inside a vehicle in order to control the ventilation system of a vehicle cabin. In particular, the control device can be arranged in an engine compartment or in a trunk.

In particular, the control device can be arranged within a mobile device in order to control the ventilation system of a mobile room, for example a marquee, a living container, a work container, an office container or a Dixie toilet. In particular, the mobile device can be arranged inside or outside the mobile space, preferably on the mobile space.

In particular, the control device can be implemented in a mobile device, for example a smartphone, a tablet or a laptop.

The object is also achieved in that a ventilation system is created which is set up to ventilate a room, in particular a vehicle cabin. The ventilation system comprises a control device which is set up to carry out a method according to the invention or a method according to one or more of the embodiments described above, in particular a control device according to the invention or a control device according to one or more of the embodiments described above, a first detection device for detecting a first spatial Position of at least one odor receiver, a second detection device for detecting a second spatial position of at least one odor source and for determining an odor intensity, and a suction device and a suction device. The control device is operatively connected to the first detection device, the second detection device, the suction device and the suction device and is set up to compare the determined odor intensity with an odor intensity threshold value, and to switch the suction device and the suction device into a first active mode if the odor intensity threshold value is exceeded by the odor intensity switch. the The control device is set up to control the suction device and the suction device in the first active mode in such a way that the air flow generated by the suction device and the suction device guides the odor away from the at least one odor receptor. In connection with the ventilation system, there are in particular the advantages that have already been explained in connection with the method and / or the control device.

According to a development of the invention, it is provided that the first detection device is additionally set up to detect the body temperature of at least one user. The control device is set up to compare the detected body temperature with a body temperature threshold and to switch the suction device and suction device into a second active mode when the body temperature threshold is exceeded. The control device is configured to control the suction device and the suction device in the second active mode in such a way that the air flow generated by the suction device and the suction device directs aerosols generated by the at least one sick user away from other users. In this way, the ventilation system advantageously directs aerosols contaminated with pathogens away from all users of a room.

In one embodiment of the invention, the first detection device comprises at least one infrared camera in order to detect the body temperature of the at least one user.

In particular, the ventilation system can be arranged on or in a property in order to ventilate the entire property, but at least one room of the property.

In particular, the ventilation system can be arranged on or in a room in order to ventilate the room.

In particular, the ventilation system can be arranged on or in a vehicle in order to ventilate a vehicle cabin.

In particular, the ventilation system can be arranged on or in a mobile room, for example on or in a fixed time, on or in a living container, on or in a work container, on or in an office container or on or in a Dixie toilet to ventilate.

In particular, the suction device has at least one fan, in particular a fan. In particular, the suction device has at least one fan, in particular a fan. In particular, the suction device has a plurality of fans, in particular fans, the suction device also having a plurality of fans, in particular fans. For the sake of simplicity, the term fan is used generically in the following, so that it includes fans on the one hand and fans in the narrower sense on the other. In particular, it is possible for one fan to be assigned to a plurality of fans both to the suction device and to the suction device. It is possible that one fan is assigned to a plurality of fans during a first time interval of the suction device, whereas the same fan is assigned to the suction device during a second time interval different from the first time interval. In particular, the one fan of a plurality of fans conveys air into a room in the first time interval, whereas the same fan conveys air out of the same room in the second time interval. In particular, the impeller of one fan of a plurality of fans rotates in both directions and thereby conveys both air into the room and air out of the room. It is also possible that the impeller of one fan of a plurality of fans only rotates in one direction, but the blades of one fan of a plurality of fans are adjustable. In particular, the suction device and the suction device can exchange their functions in the manner shown here.

In particular, the at least one fan is connected to the environment outside the room via an air duct. In particular, the at least one fan is connected to the environment outside the room via a plurality of air ducts. In particular, the air ducts are divided into suction air ducts for suction and suction air ducts for suction. In particular, the at least one fan is connected both to an intake air duct and to an exhaust air duct. In particular, the fan is fluidically connected to the intake air duct or to the exhaust air duct via a switchover flap.

According to a development of the invention it is provided that the first detection device is at least one camera. Alternatively or additionally, the second detection device is at least one gas sensor. In particular, the first detection device additionally comprises seat occupancy mats. In this way, a first spatial position and a second spatial position are advantageously detected.

In particular, the second detection device has a plurality of second Partial detection devices. In particular, every second partial detection device is a gas sensor.

In particular, the second spatial position, that is to say the position of an odor source, is preferably determined in that the position of a second partial detection device of the second detection device which detects the odor is determined as the second spatial position. In particular, it is therefore possible that a second partial detection device of the second detection device, preferably a single gas sensor, detects an odor and then it is determined that the odor source is at the spatial position of the second partial detection device of the second detection device, i.e. at the spatial position of the gas sensor.

In particular, a second spatial position of an odor source is determined in that at least two second partial detection devices of the second detection device, preferably at least two gas sensors, work together. If two second partial detection devices of the second detection device detect the same odor with the same odor intensity, it is determined that the spatial position of the odor source is in the middle of an imaginary connecting line between the two second partial detection devices of the second detection device. If two second partial detection devices of the second detection device detect the same odor with different odor intensity, for example in a ratio of 1: 2, it is determined that the spatial position of the odor source is not in the middle of an imaginary connecting line between the two second partial detection devices of the second detection device, but closer in the direction of one of the two second partial detection devices of the second detection device. In particular, the odor source is located closer to that second partial detection device of the two partial detection devices which detects a higher odor intensity than the other second partial detection device of the two partial detection devices. In particular, in the case of a second detection device that consists of a plurality of second partial detection devices, that is a plurality of gas sensors, it is possible for the spatial position of the odor source to be detected as precisely as possible.

According to a further development of the invention it is provided that the ventilation system has an actuating device. The actuating device is operatively connected to the suction device and the suction device and is set up in such a way that a user can manually switch the suction device and suction device operated in the idle mode to the first or second active mode. In this way, the user can advantageously, in particular also discreetly and without other users noticing, switch the suction device and suction device operated in the idle mode to the first or the second active mode.

In particular, the actuation device is a switch on the ventilation system. In particular, the switch is assigned to a seat and is arranged in the vicinity of the assigned seat. In particular, a user who suffers from outgassing can manually switch the suction device and suction device operated in the idle mode to the first active mode. In particular, a user who feels sick and / or is sick can manually switch the suction device and suction device operated in the idle mode to the second active mode.

In one embodiment of the invention, the actuation device is a receiver on the ventilation system. In particular, the receiver on the ventilation system is a Bluetooth receiver with which a user connects to an electronic device. In particular, the user then uses the electronic device, preferably a smartphone, a tablet or a laptop, to manually switch the suction device and suction device operated in the idle mode to the first or second active mode.

The object is also achieved in that a vehicle, in particular a passenger car or a bus, is created with a ventilation system according to the invention or a ventilation system according to one or more of the embodiments described above. In connection with the vehicle, there are in particular the advantages that have already been explained in connection with the method and the ventilation system.

• 1 Ein Flussdiagramm eines ersten Ausführungsbeispiels eines Verfahrens zum Betreiben eines Belüftungssystems in einem Teilbereich eines Raumes,
• 2 Ein Flussdiagramm eines zweiten Ausführungsbeispiels eines Verfahrens zum Betreiben eines Belüftungssystems mit wenigstens zwei Teilbereichen eines Raumes, und
• 3 Eine schematische Darstellung eines Belüftungssystems zur Durchführung eines erfindungsgemäßen Verfahrens, angeordnet an einem Bus

The invention is explained in more detail below with reference to the drawing. Show:

• 1 A flowchart of a first exemplary embodiment of a method for operating a ventilation system in a sub-area of a room,
• 2 A flowchart of a second exemplary embodiment of a method for operating a ventilation system with at least two partial areas of a room, and
• 3 A schematic representation of a ventilation system for carrying out a method according to the invention, arranged on a bus

• In einem ersten Schritt S1 wird das Belüftungssystem im Ruhemodus betrieben. In einem zweiten Schritt S2 wird eine erste räumliche Position wenigstens einer Geruchsquelle eines Geruchs detektiert. In einem dritten Schritt S3 wird eine zweite räumliche Position wenigstens eines Geruchsempfängers detektiert. In einem vierten Schritt S4 wird eine

1 FIG. 3 shows a flow diagram of a first exemplary embodiment of a method for operating a ventilation system for ventilating a Partial area of a room, preferably an individual seat of a room, the method according to the algorithm described below 1 expires:

• In a first step S1 the ventilation system is operated in sleep mode. In a second step S2 a first spatial position of at least one odor source of an odor is detected. In a third step S3 a second spatial position of at least one odor receiver is detected. In a fourth step S4 becomes a

Odor intensity of the odor determined. In a fifth step S5 the determined odor intensity is compared with a predetermined odor intensity threshold value.

If the odor intensity exceeds the predetermined odor intensity threshold value, then in a sixth step S6 a suction device and a suction device switched to a first active mode, the suction device and the suction device being controlled in the first active mode in such a way that the air flow generated by the suction device and the suction device guides the odor away from the at least one odor receptor.

If the suction device and the suction device are in the first active mode, a first loop 2 back to the third step S3 jumped. The steps S3 until S6 are repeated until the odor intensity exceeds the odor intensity threshold in the fifth step S5 falls below.

If the odor intensity falls below the odor intensity threshold value in the fifth step S5 , will be in a second loop 3 back to the first step S1 jumped and the suction device and the suction device switched from the first active mode to the sleep mode. The algorithm starts again at the first step S1 .

• In einem ersten Schritt wird das Belüftungssystem im Ruhemodus betrieben. In einem zweiten Schritt wird eine Körpertemperatur wenigstens eines Nutzers erfasst. In einem dritten Schritt wird die erfasste Körpertemperatur mit einem vorbestimmten Körpertemperaturschwellenwert verglichen.

In an exemplary embodiment not shown here, the second active mode is treated analogously:

• In a first step, the ventilation system is operated in sleep mode. In a second step, a body temperature of at least one user is recorded. In a third step, the detected body temperature is compared with a predetermined body temperature threshold value.

If the detected body temperature exceeds the predetermined body temperature threshold, then in a fourth step a suction device and a suction device are switched to a second active mode, the suction device and the suction device being controlled in the second active mode in such a way that the air flow generated by the suction device and the suction device diverts aerosols generated by the at least one sick user away from other users.

If the suction device and the suction device are in the second active mode, a jump is made back to the second step in a first loop. The second, third and fourth step are repeated until the temperature recorded as body temperature falls below the body temperature threshold value in the third step, for example until the sick user has left the room again.

If the temperature recorded as body temperature falls below the body temperature threshold value in the third step, a jump is made back to the first step in a second loop and the suction device and the suction device are switched from the second active mode to the sleep mode. The algorithm starts again at the first step.

2 FIG. 3 shows a flow diagram of a second exemplary embodiment of a method for operating a ventilation system with at least two sub-areas of a room, the algorithm in each sub-area 1 according to the embodiment of 1 expires.

The procedure begins with an eleventh step S11 , in which the ventilation system is preferably switched on.

In a first, twelfth step S12 .1 becomes the algorithm for a first part of the room 1 according to the embodiment of 1 run through. At the same time or at different times, a second, twelfth step will take place S12.2 for a second part of the room likewise the algorithm 1 according to the embodiment of 1 run through. In parallel to this or at a different time, there is an N-th twelfth step S12.N for a plurality of sub-areas, preferably for N Sections of the room, where N is a natural number and stands for the number of sub-areas, likewise the algorithm 1 according to the embodiment of 1 run through.

The procedure ends with a thirteenth step S13 , in which preferably the ventilation system is switched off.

3 shows a ventilation system 5 which is set up to ventilate a bus 7th . That Ventilation system 5 comprises a control device 9 which is set up to carry out a method according to the invention or a method according to one or more of the embodiments described above.

The ventilation system 5 is used below for a seat 11 of the bus 7th described.

The ventilation system 5 comprises a first detection device 13th . The first detection device 13th has at least one camera 15th on. For a better overview, only one of the cameras is 15th provided with a reference number. The camera 15th detects a first spatial position 17th at least one odor receiver 19th .

The ventilation system 5 comprises a second detection device 21 . The second detection device 21 has at least one gas sensor 23 on. For the sake of clarity, only one of the gas sensors is there 23 provided with a reference number. The gas sensor 23 detects a second spatial position 25th at least one source of odor 27 and determines the odor intensity of the odor source 27 emitted odor.

The ventilation system 5 includes a suction device 29 and a suction device 31 . The suction device preferably has 29 a plurality of fans 33 on, including the suction device 31 a plurality of fans 33 having. For the sake of clarity, there is only one of the fans 33 provided with a reference number.

It is preferably possible that a fan 33 a plurality of fans 33 both the suction device 29 as well as the suction device 31 assigned. It is possible that the one fan 33 a plurality of fans 33 during a first time interval of the aspirator 29 assigned, whereas the same fan 33 during a second time interval of the suction device which differs from the first time interval 31 assigned. Preferably one fan promotes 33 a plurality of fans 33 in the first time interval air into the bus 7th into it, whereas the same fan 33 in the second time interval air from the same bus 7th promotes out.

The control device 9 is with the first detection device 13th , the second detection device 21 , the suction device 29 and the suction device 31 Operationally connected and set up to compare the determined odor intensity with an odor intensity threshold value, the suction device 29 and the suction device 31 to switch to a first active mode when the odor intensity threshold value is exceeded by the odor intensity, and the suction device 29 and the suction device 31 to control in the first active mode in such a way that that of the suction device 29 and from the suction device 31 air flow generated the odor from the at least one odor receptor 19th leads away.

In another embodiment of the exemplary embodiment, the control device is 9 with the first detection device 13th , the second detection device 21 , the suction device 29 and the suction device 31 operatively connected and set up to compare the detected body temperature with a predetermined body temperature threshold value, the suction device 29 and the suction device 31 to switch to a second active mode when the predetermined body temperature threshold value is exceeded by the detected body temperature, and to switch the suction device 29 and the suction device 31 in the second active mode to control that of the suction device 29 and from the suction device 31 generated airflow from the at least one sick user 19th diverts generated aerosols away from other users.

The ventilation system 5 has at least one actuating device 35 which is operatively connected to the suction device and to the suction device and is set up in such a way that a user can use the suction device operated in the idle mode 29 and suction device 31 can manually switch to the first active mode.

QUOTES INCLUDED IN THE DESCRIPTION

This list of the documents listed by the applicant was 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.

Patent literature cited

• US 2011/0319004 A1 [0002]
• US 8083575 B2 [0002]

Claims (10)

Method for operating a ventilation system (5) for ventilating a room, in particular a vehicle cabin, wherein - A first spatial position (17) of at least one odor receiver (19) is detected, wherein - A second spatial position (25) of at least one odor source (27) of an odor is detected, wherein - An odor intensity of the odor is determined, wherein - The determined odor intensity is compared with a predetermined odor intensity threshold value, wherein - A suction device (29) and a suction device (31) are switched into a first active mode when the determined odor intensity exceeds the predetermined odor intensity threshold value, wherein - The suction device (29) and the suction device (31) are controlled in the first active mode in such a way that - The air flow generated by the suction device (29) and by the suction device (31) guides the odor away from the at least one odor receiver (19). Method according to one of the preceding claims, wherein the air flow is controlled in such a way that the air flow from the suction device (29) to the at least one odor receiver (19), then to the at least one odor source (27), and then to the suction device (31) flows. The method according to any one of the preceding claims, wherein - a body temperature of at least one user is recorded, wherein - The detected body temperature is compared with a predetermined body temperature threshold value, wherein - The suction device (29) and the suction device (31) are switched into a second active mode when the detected body temperature exceeds the predetermined body temperature threshold value, wherein - The suction device (29) and the suction device (31) are controlled in the second active mode in such a way that - The air flow generated by the suction device (29) and by the suction device (31) diverts aerosols generated by the at least one sick user away from other users. The method according to any one of the preceding claims, wherein - The suction device (29) and the suction device (31) are operated in a rest mode when the determined odor intensity falls below the predetermined odor intensity threshold value and / or when the detected body temperature falls below the predetermined body temperature threshold value, wherein - The suction device (29) and the suction device (31) convey less air in the rest mode than in the first active mode and in the second active mode. Control device (9), set up by performing a method according to one of the preceding claims. Ventilation system (5) which is set up to ventilate a room, in particular a vehicle cabin, with - a control device (9) according to Claim 5 - a first detection device (13) for detecting a first spatial position (17) of at least one odor receiver (19), - a second detection device (21) for detecting a second spatial position (25) of at least one odor source (27), and for determination an odor intensity, - a suction device (29) and a suction device (31), wherein the control device (9) is operatively connected to the first detection device (13), the second detection device (21), the suction device (29) and the suction device (31) and is set up to - compare the determined odor intensity with an odor intensity threshold value, - switch the suction device (29) and the suction device (31) into a first active mode when the odor intensity threshold value is exceeded by the odor intensity, and - the suction device (29) and the suction device (31) to control in the first active mode, - that of the suction device (29) and the air flow generated by the suction device (31) guides the odor away from the at least one odor receiver (19). Ventilation system (5) Claim 6 wherein - the first detection device (13) is set up to detect the body temperature of at least one user, wherein - the control device (9) is set up to compare the detected body temperature with a body temperature threshold in order to - when the body temperature threshold is exceeded by the body temperature to switch the suction device (29) and suction device (31) into a second active mode, and to - control the suction device (29) and the suction device (31) in the second active mode in such a way that - the of the suction device (29) and of the suction device (31) generated air flow from the diverts aerosols generated by at least one sick user away from other users. Ventilation system (5) Claim 6 or 7th wherein - the first detection device (13) is at least one camera (15), and / or - the second detection device (21) is at least one gas sensor (23). Ventilation system (5) Claim 6 , 7th or 8th , with at least one actuating device (35) which is operatively connected to the suction device (29) and to the suction device (31) and is set up in such a way that a user can manually insert the suction device (29) and suction device (31) operated in the idle mode into the first or second active mode can switch. Vehicle, in particular a passenger car or bus (7), with a ventilation system (5) Claim 6 until 9 .

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