WO2018206354A1 - Method and evaluation unit for determining the condition of an air filter - Google Patents

Abstract

The invention describes an evaluation unit (101) for a ventilation system (100). The ventilation system (100) is designed to convey air (120) through an air channel (102) into a region (122) to be ventilated. The ventilation system (100) comprises an air filter (107) and a particle sensor (111) in the air channel (102). The evaluation unit is configured (101) to use the particle sensor (111) to determine particle sensor data that indicates a number and/or amount of particles in the air (120) in the air channel (102), said air having passed through the air filter (107). The evaluation unit (101) is also configured to determine a deposit accumulation condition (202) of the air filter (107) based on the particle sensor data and based on characteristic data (203) in relation to a particle separation capacity (201) of the air filter (107).

Description

 Method and evaluation unit for determining the state of an air filter

The invention relates to a method and an evaluation unit for determining the condition of a filter of a ventilation system, in particular a ventilation system of a vehicle.

A vehicle typically includes a ventilation system with which air (e.g., fresh air and / or recirculating air or air from the interior of the vehicle) is introduced into the vehicle

Interior of the vehicle can be promoted. The ventilation system includes

typically a fan that may be operated at different strengths to deliver more or less air into the interior of the vehicle. Furthermore, the ventilation system may comprise a particle sensor with which particle sensor data relating to the particle load (in particular the particulate matter load) of the air which is conveyed into the interior of the vehicle can be detected. In particular, the particulate sensor may be configured to detect particulate sensor data relating to the concentration of particulates (e.g., particulate matter) per unit volume in the conveyed air.

It can thus be determined on the basis of the particle sensor data information with respect to the air quality and possibly displayed to a user of the vehicle. Alternatively or additionally, the ventilation system (e.g., the fan's capacity or a venting system closure element) may be controlled in dependence on the particulate sensor data.

The ventilation system can be an air filter, in particular a particle and / or

Fine dust filter, which is adapted to reduce the particle concentration in the air, which is conveyed into the interior of the vehicle. Thus, the air quality in the interior of a vehicle can be increased. The absorption capacity of an air filter for impurities from the air typically depends on the condition, in particular on the degree of occupancy, of the air filter.

The present document deals with the technical problem of providing a method and an evaluation unit, by means of which the condition of an air filter, in particular the degree of occupancy of an air filter, can be determined in a precise and efficient manner. The object is solved by the independent claims. advantageous

Embodiments are described i.a. in the dependent claims. It should be noted that additional features of a claim dependent on an independent claim without the features of the independent claim or only in combination with a subset of the features of the independent claim may form an independent invention independent of the combination of all features of the independent claim, the subject of an independent claim, a divisional application or a subsequent application. This applies equally to technical teachings described in the specification, which may form an independent invention of the features of the independent claims.

According to one aspect, an evaluation unit for a ventilation system is described. The ventilation system may be part of a motor vehicle and may be configured to

To ventilate the interior or the passenger cabin of the motor vehicle. In this case, air, in particular air from the surroundings of the vehicle, can be conveyed via an air channel into the interior of the vehicle. The interior of a vehicle is an example of an area to be ventilated by a ventilation system.

The ventilation system can be designed to convey different volumes and / or time-varying volumes of air through the air duct into the area to be ventilated. In other words, the volume flow and / or the mass flow of air flowing through the air duct into the area to be ventilated may change over time. The ventilation system may in particular comprise a fan, which is set up with different fan strengths different volumes or masses of air through the air duct (eg through a pipe) in the area to be ventilated (eg in the interior of a vehicle or in another room with breathing air and / or working air). The fan strength may e.g. by a user of the ventilation system via a control (e.g., stepwise). Alternatively or additionally, the fan power can be automatically adjusted by an automatic climate control of the vehicle, e.g. in

Dependence on a difference between a (measured) actual temperature and a desired temperature (eg predetermined by a user). The ventilation system comprises a particle sensor arranged in the air duct. The particle sensor can be set up to detect particle sensor data indicating the number and / or amount of particles (eg measured in ppm, parts per million, or in g, grams) in the air in the air channel (eg per unit time or per unit volume).

For example, for this purpose, the particle sensor may comprise an optical sensor arranged to provide sensor data relating to an amount of light scattering, e.g. to detect a degree of light scattering in the air channel. For example, a light curtain can be generated inside the particle sensor and / or inside the air channel, through which the air flows with particles at a certain speed. The speed of the air may depend on the fan power. As it passes through the light curtain, one (e.g., every) fraction of the particles in the air deflects light from its path to a light receiving unit of the particle sensor. The logic in the sensor evaluates the pulses of the deflected light on the receiving unit. In particular, on the basis of the pulses, the number and / or amount of particles per unit of time or per

Volume unit can be determined.

In addition, the ventilation system in the air duct comprises an air filter. The air filter is arranged upstream with respect to a flow direction of the air with respect to the particle sensor. The particle sensor can thus detect particle sensor data relating to the air at the outlet of the air filter. In other words, the particulate sensor data may indicate the number and / or amount of particulate matter in the air that has passed through the air filter.

The evaluation unit can be set up to determine particle sensor data on the basis of the particle sensor. In addition, the evaluation unit may be configured to determine the occupancy state of the air filter on the basis of the particle sensor data and on the basis of characteristic data relating to a particle separation performance of the air filter.

By taking into account the particle sensor data and by taking into account characteristics relating to the separation efficiency of an air filter, the occupancy state, in particular the degree of occupancy, of an air filter can be determined in a precise and efficient manner. The characteristics of the air filter may indicate the particle separation efficiency of the air filter depending on the occupancy state of the air filter. In particular, the characteristics may include a characteristic that indicates the particle separation efficiency of the air filter as a function of the occupancy state of the air filter. The characteristic data can be determined by measurements in advance and stored on a storage unit of the ventilation system and thus made available to the evaluation unit.

The air filter may include a machine-readable code (e.g., a bar code or a QR code) that enables the evaluation unit to determine the characteristics of the air filter. For example, the machine-readable code may indicate a link to a location where the characteristics for the air filter are stored. So can the

Characteristics are provided in an efficient manner for different types of air filters. The ventilation system may for this purpose comprise a reading device which is adapted to detect the machine-readable code of the air filter. Furthermore, the ventilation system may include a communication unit to access the location of the characteristics.

Alternatively or additionally, the characteristic data for the air filter can be determined depending on one or more properties of the vehicle in which the air filter is arranged. The one or more characteristics of the vehicle may be e.g. include: a manufacturer of the vehicle; a model name of the vehicle; a year of construction of the vehicle; a regional and / or country-dependent variant of the vehicle; and / or one or more optional extras of the vehicle. The evaluation unit may be configured to determine the characteristics for the air filter on the basis of one or more properties of the vehicle in which the air filter is installed.

Particulate removal efficiency may indicate a number and / or amount of particulates that may be received by the air filter per unit volume and / or per unit mass of air passing through the air filter. Alternatively or additionally, the particle separation performance can indicate a proportion of particles in the air passing through the air filter, which can be filtered out of the air by the air filter. In particular, the particle separation efficiency can be such that the number and / or amount of particles on the basis of the particle sensor data and on the basis of the particle separation performance

Input of the air filter can be determined. In other words, the particle Separation efficiency can make it possible to determine from the number and / or amount of particles in the air at the outlet of the air filter, the number and / or amount of particles in the air at the entrance of the air filter.

The occupancy state of the air filter may indicate a number and / or amount of particles that have already been taken up by the air filter and / or that may still be picked up by the air filter. Alternatively or additionally, the

Occupancy state indicate a proportion of a total absorption capacity of particles of the air filter that has already been used up or that is still available for the absorption of particles. The total capacity of an air filter can indicate the total number and / or amount of particles that can be absorbed by the air filter during the lifetime of an air filter. The occupancy state can thus indicate how long an air filter can still be used to filter the air in a ventilation system and / or what number and / or amount of particles can still be absorbed by the air filter as a whole.

The evaluation unit may be set up to determine air quality information x (t _n ) based on the particle sensor data at a specific point in time t _n , which indicates the number and / or quantity of particles which at the specific time t _n in the Air is present at the outlet of the air filter. It can then be determined on the basis of the characteristics and on the basis of the air quality information x (t _n ) recording information y (t _n ) indicating the number and / or amount of particles that at the specific time t _n of the Air filters were added.

In particular, an occupancy state Y (t _n -) of the air filter can be determined at a time t _n _ _x preceding the determined time t _n . On the basis of the characteristic data A (Y) of the air filter, in particular on the basis of a characteristic curve A (Y), which indicates the particle absorption capacity A as a function of the occupation state Y, then the particle absorption power A (Y (t _{n-- 1} ) ) of the air filter at the preceding time t _n _ _x . From the particulate uptake power i (F (t _n _ ₁ )) of the air filter at the preceding time t _n _ _x and the air quality information x (t _n ) at the specific time t _n , the recording information y (t _n ) are determined at the specific time t _n , eg as yft ") = ^ * ^ ^{7" 1} ^ x (t _v ). The occupancy state Y (t _n -i) of the air filter at the previous time t _n _ may then be updated with the reception information y (t _n ) for the specific time t _n to indicate the occupancy state Y (t _n ) of the air filter at the specific time t _n , eg as Y (t _n ) =

It can thus iteratively or recursively for a sequence of times t _n , with n = 1, ..., N, the current occupancy state of an air filter are determined. In this case, the time t ₀ corresponding to an initial time (eg when commissioning an air filter). On the other hand, the time t _{N may} correspond to a current time. The time interval between two adjacent times t _n _ _x and t _n corresponds to an update frequency.

The evaluation unit may thus be arranged recursively or iteratively on the basis of the particle sensor data for a sequence of time points from an initial point in time, on the basis of the characteristic data and on the basis of an initial occupancy state of the air filter at the start time, the occupancy state of the air filter to determine the sequence of times. The initial occupancy state of the air filter may be the occupancy state of the air filter at the initial start-up of the air filter. Alternatively or additionally, the initial occupancy state of the air filter may be the occupancy state of the air filter during a (re) startup of the ventilation system (e.g., at engine startup of a vehicle). The initial occupancy state can be on a

Storage unit of the ventilation system to be stored and thus provided to the evaluation unit.

As already stated above, the ventilation system may include a fan which is designed to promote different volumes of air through the air duct (and thus through the air filter) into the area to be ventilated with different fan strengths. The evaluation unit can be set up, a time interval or a

Update frequency of the timing of the sequence of times for updating the occupancy state of the air filter in response to the fan strength to adjust. In particular, the time interval with increasing volume of air through the

Air duct, ie with increasing fan strength, can be reduced. Thus, the accuracy of the detected occupancy state can be increased efficiently. The evaluation unit may be configured to cause information related to the occupancy state of the air filter to be output to a user of the ventilation system. In particular, it can be determined whether the degree of occupancy of the air filter is greater than an occupancy level threshold. If so, an indication may be issued to a user to cause the user to replace the air filter. This can improve the air quality in a ventilated area.

In another aspect, a ventilation system is described. The

Ventilation system includes an air duct. Furthermore, the ventilation system comprises an air filter that is configured to reduce a number and / or amount of particles in the air in the air duct. In particular, the number and / or amount of particles which are conveyed via the air duct into a region to be ventilated can be reduced by the air filter.

The ventilation system further includes a particulate sensor disposed in the air passage and configured to detect particulate sensor data indicative of the number and / or amount of particulates in the air in the air passage that has passed through the air filter. In addition, the ventilation system includes the evaluation unit described in this document.

According to another aspect, a method for determining an occupancy state of an air filter of a ventilation system is described. The ventilation system is designed to convey air through an air duct into a region to be ventilated. The ventilation system comprises in the air duct the air filter and a particle sensor. The method includes determining, based on the particulate sensor, particulate sensor data indicative of a number and / or amount of particulates in the air in the air passage that has passed through the air filter. In addition, the method comprises determining, on the basis of the particle sensor data and on the basis of characteristics relating to a particle separation efficiency of the air filter, the

Occupancy state of the air filter.

The process can be repeated regularly, e.g. with a certain

Update frequency (for example, every second) to the current one

Determine occupancy status. According to a further aspect, a vehicle (in particular a road motor vehicle eg a passenger car or a lorry) is described, which describes the ventilation system described in this document and / or that described in this document

Evaluation unit includes.

In another aspect, a software (SW) program is described. The SW program can be set up to run on a processor (e.g.

Evaluation unit) to be executed, and thereby in this document

to carry out the described method.

In another aspect, a storage medium is described. The storage medium may include a SW program that is set up to run on a processor and thereby perform the method described in this document.

It should be understood that the methods, devices and systems described herein may be used alone as well as in combination with other methods, devices and systems described in this document. Furthermore, any aspects of the methods, devices, and systems described herein may be combined in a variety of ways.

In particular, the features of the claims can be combined in a variety of ways.

Furthermore, the invention will be described in more detail with reference to exemplary embodiments. Show

 Figure 1 shows the structure of an exemplary ventilation system;

 Figure 2 exemplary characteristics of the capacity of an air filter; and

 FIG. 3 shows a flow diagram of an exemplary method for determining the condition of an air filter.

As stated above, the present document is concerned with the efficient and precise determination of the condition of an air filter of a ventilation system. In this

1 shows an exemplary ventilation system 100 with an air channel 102, through which air 120 is conveyed from a first region 121 into a second region 122 can be. The first region 121 may be the environment of a vehicle and the second region 122 may be the interior of a vehicle. The ventilation system 100 has

typically includes a fan 104 (or other type of air mass flow adjusting unit) configured to convey air 120 through the air passage 102. In this case, the fan 104 can be operated with different strengths (eg stepwise) in order to change the air volume V conveyed by the fan 104 per unit of time (measured, for example, in m ³ / s). Furthermore, the air duct 102 can have a valve or a flap 103 (as a closure element), with which the air duct 102 can be closed partially or completely (eg stepwise or flowing).

The ventilation system 100 further comprises a particle sensor 111, which is set up, particle sensor data with respect to a number N of particles per unit time (measured, for example, in ppm / s) and / or per unit volume (measured, for example, in ppm / m ³ ) capture.

Alternatively or additionally, the particle sensor 111 can be set up, a particle concentration P per air volume unit (measured, for example, in particle number per volume, ie ppm / m ³ , and / or in weight per volume, ie g / m ³ ) in the air 120 to determine.

The particle sensor 111 may be e.g. an optical sensor configured to detect an amount of optical dispersion. From the extent of the optical scattering can be concluded then on the number N of particles or on the weight of particles. The particle sensor 111 may be arranged in a separate area 110 within the air channel 102.

The ventilation system 100 may further include a temperature control unit 106 that is configured to temper the air 120. The temperature control unit 106 may, as shown in FIG. 1, be arranged upstream with respect to the particle sensor 111. Thus, air 120 may be caused to flow past the particulate sensor 111 that is displaced from the

Temperature control unit 106 was tempered (for example, to a certain target temperature). The tempering unit 106 may be configured to cool or heat the air 120 from the first region 121. A user of the ventilation system 100 may specify a desired temperature for the second region 122 and the temperature control unit 106 may be operated in dependence on the desired temperature. The by the

Tempering unit 106 set air temperature and / or air humidity of the air 120 may in the determination of the air quality in the ventilation system 100 and / or be considered in the determination of the occupancy state of an air filter 107 of the ventilation system 100.

The ventilation system 100 may further include one or more property sensors 105 configured to acquire property sensor data relating to a property of the air 120 in the air duct 102. Exemplary properties are the humidity and the temperature of the air 120.

In addition, the ventilation system 100 comprises an air filter 107, in particular a particle filter, which is set up to reduce the number and / or the concentration of particles in the air 120 in the air duct 102. The particle sensor 111 may be configured to determine the number N of particles or the particle concentration P of the air 120, which has already passed through the air filter 107. The air 120 which has passed through the air filter 107 typically has a reduced number N of particles or a reduced particle concentration P, respectively.

An air filter 107 has a capacity for absorbing particles, which typically depends on the condition of the air filter 107, in particular on the degree of occupancy of the air filter 107. FIG. 2 shows exemplary characteristics relating to the capacity of a

Air filter 107. In particular, Fig. 2 shows a characteristic curve 203 for the separation efficiency 201 of an air filter 107 as a function of the degree of occupancy 202 of the air filter 107th Die

Abscheideleistung 201 can

The number or amount of particles that can be filtered from air 120 per unit volume of air 120 (measured in ppm / m ³ or in g / m ³ ); and or

• Display the percentage of particulates that can be filtered from the air 120 (measured in).

The occupancy status or occupancy level 202 can

 • indicate the number or amount of particles already present from the air filter 107

 and / or which can still be picked up by the air filter 107 (e.g., measured in ppm or g); and or

• indicate the proportion of the total capacity of the air filter 107 that is still available for the uptake of particles (eg measured in%). The separation efficiency 201 of an air filter 107 depends on the occupancy state or

Occupancy rate 202 of the air filter 107 from. Typically, the separation efficiency 201 decreases as the occupancy rate 202 increases. Once the overall capacity of an air filter 107 is reached, the air filter 107 typically no longer has a filtering effect (i.e., a zero separation efficiency 201) so that air 120 is conveyed unfiltered into the second region 122. The degree of occupancy 202 of the air filter 107 is 100% in this case.

On the other hand, when the air filter 107 is first put into operation, the air filter 107 typically has a degree of occupancy 202 of 0% and a maximum possible

Separation efficiency 201 on.

The evaluation unit 101 may be configured to change the state, in particular the

Occupancy degree 202, an air filter 107 to determine. In particular, it can be determined whether the degree of occupancy 202 of an air filter 107 reaches or exceeds a certain occupancy level threshold. An indication may then be issued to a user of the ventilation system 100 to indicate to the user that the air filter 107 should be replaced or cleaned to increase the separation efficiency 201.

The evaluation unit 101 can determine the quantity x (t) of particles in the air 120 after passing through the air filter 107 on the basis of the particle sensor 111 as air quality information (as a function of the time t). Furthermore, the evaluation unit 101 knows, based on the characteristics of the air filter 107, the separation efficiency 201 of the air filter 107 as a function of the degree of loading 202, i. A (Y), where Y is occupancy level 202 (eg, the amount of particles already taken up by air filter 107), and where A (Y) is separation efficiency 201 (eg, A (Y) can indicate the proportion of particles. which can be filtered by the air filter 107 from the air 120).

From the quantity x (t) of particles in the air 120 measured at a point in time t after passing through the air filter 107, the quantity y (t) of particles which are measured on the particles can be determined

 A (Y)

Time t were taken from the air filter 107, with y (t) = _{1 + A} ^ x (t, where A is the separation efficiency 201 of the air filter 107 at time t.

The amount Y of particles that has been taken up by the air filter 107 as a whole (ie, the actual occupancy level 202) then becomes an integral over the operating time of the air filter 107 as Y = J ^f y (t) dt, where t _{0 is} the start time at which the air filter 107 has been put into operation.

The evaluation unit 101 can thus on the basis of the particle sensor data of the particle sensor 111 during the life of an air filter 107 and on the basis of characteristics 203 with respect to the capacity of the air filter 107 at any time the

Occupancy status or occupancy level 202 of the air filter 107 determine.

The particle sensor 111 can thus be used to detect the filter occupancy of an air filter 107. An air filter 107 has a curve or characteristic 203, which represents the separation capacity 201 of the air filter 107 as a function of the filter occupancy 202. New filters 107 typically pass fewer particles than dirty filters 107. The curve 203 of separation efficiency 201 versus filter loading 202 may be determined in advance (e.g., through experiments).

With the aid of the known curve 203, the air 120 can be continuously analyzed based on the fine dust concentration x (t) measured by the particle sensor 111 and passed through the filter 107 to the fine dust concentration z (t) = x (t) + y (t) the filter 107 are closed. The difference between the two values gives the deposited particle quantity or the weight of the deposited particles y (t). The deposited particle quantity or its weight y (t) is integrated in order to determine the current filter loading Y. On the basis of the current filter load Y can be inferred by taking into account the curve 203 in turn to the current separation efficiency 201 of the filter 107. Thus, the end of life or the remaining life of a filter 107 can be determined. This information can be displayed to a user of a ventilation system 100 via a display unit.

3 shows a flowchart of an exemplary method 300 for determining the occupancy state 202 (in particular of occupancy level 202) of an air filter 107 of a ventilation system 100. The ventilation system 100 is designed to convey air 120 through an air channel 102 into a region 122 to be ventilated , In addition, the ventilation system 100 in the air passage 102 includes the air filter 107 and a particle sensor 111. Here, the particle sensor 111 is disposed downstream of the air filter 107 with respect to a flow direction of the air 120. The method 300 includes determining 301, based on the particle sensor 111, of particle sensor data indicating a number and / or amount of particles in the air 120 in the air passage 102 that has passed through the air filter 107. In addition, the method 300 includes determining 302, based on the particle sensor data and based on characteristic data 203 relating to a particle separation capacity 201 of the air filter 107, the occupancy state 202 of the air filter 107. The characteristics 203 may be determined in advance (eg in the development of the Air filter 107) determined, in particular measured be.

With the measures described in this document, the current filter occupancy of an air filter 107 of a ventilation system 100 can be determined in a precise and efficient manner. Thus, the remaining time of an air filter 107 can be determined and displayed.

As a result, an appropriate change of an air filter 107 is made possible. Furthermore, the operation with an ineffective filter 107 is avoided. Thus, the air quality in an area to be ventilated 122 can be increased.

On the basis of the particle sensor data and on the basis of the characteristic data 203, the number and / or quantity z (t) of particles at the inlet of the air filter 107 can be determined. This number and / or quantity z (t) of particles may possibly be implausible. Thus, e.g. a faulty or inappropriate air filter 107 is detected. The evaluation unit 101 can thus be set up to detect a defect of the air filter 107 on the basis of the particle sensor data and on the basis of the characteristic data 203 of an air filter 107 and / or to detect that an inappropriate air filter 107 is used in the ventilation system 100.

The present invention is not limited to the embodiments shown. In particular, it should be noted that the description and figures are intended to illustrate only the principle of the proposed methods, apparatus and systems.

Claims

 claims

1) evaluation unit (101) for a ventilation system (100); wherein the ventilation system (100) is designed to convey air (120) through an air duct (102) into a region (122) to be ventilated; wherein the ventilation system (100) in the air duct (102) comprises an air filter (107) and a particle sensor (111); wherein the evaluation unit (101) is set up,

 - using the particle sensor (111) to determine particle sensor data indicating a number and / or amount of particles in the air (120) in the air duct (102) that has passed through the air filter (107); and

 - Based on the particle sensor data and on the basis of characteristics (203) with respect to a particle separation efficiency (201) of the air filter (107) a

 Occupancy state (202) of the air filter (107) to determine.

2) evaluation unit (101) according to claim 1, wherein

 the characteristic data (203) indicate the particle separation capacity (201) of the air filter (107) as a function of the occupancy state (202) of the air filter (107); and

- The characteristic data (203) in particular a characteristic curve (203) indicating the particle separation efficiency (201) of the air filter (107) as a function of the occupancy state (202).

3) Evaluation unit (101) according to one of the preceding claims, wherein the particle separation efficiency (201) indicates

 a number and / or amount of particles coming from the air filter (107) per

 Volume unit and / or per unit mass of air (120) passing through the air filter (107) can be recorded; and or

 a proportion of particles in the air filter (107) passing through the air (102) which can be filtered out of the air (120) from the air filter (107).

4) evaluation unit (101) according to one of the preceding claims, wherein the

 Occupancy state (202) of the air filter (107) indicates

a number and / or quantity of particles already taken up by the air filter (107); and or - A proportion of a total absorption capacity of particles of the air filter (107), which has already been used or is still available for the inclusion of particles.

5) evaluation unit (101) according to one of the preceding claims, wherein the

 Evaluation unit (101) is set up,

 on the basis of the particle sensor data at a certain time, to determine air quality information indicating the number and / or amount of particulates present at the particular point in the air (120) at an exit of the air filter (107); and

 based on the characteristics (203) and on the basis of the air quality information,

 To determine acquisition information indicating the number and / or amount of particulates taken up by the air filter (107) at the designated time.

6) evaluation unit (101) according to claim 5, wherein the evaluation unit (101) is set up,

 to determine an occupancy state (201) of the air filter (201) at a time preceding the particular time; and

 the occupancy state (201) of the air filter (201) on the preceding one

 Update timing with the recording information for the specific time to determine the occupancy state (201) of the air filter (107) at the specific time.

7) evaluation unit (101) according to one of the preceding claims, wherein the

 Evaluation unit (101) is set up on the basis of the particle sensor data for a sequence of times from an initial point in time, on the basis of the characteristic data (203) and on the basis of an initial occupancy state (202) of the air filter (107) at the start point. Time recursively determine the occupancy state (202) of the air filter (107) at the sequence of times.

8) evaluation unit (101) according to claim 7, wherein - The ventilation system (100) comprises a fan (104) which is adapted to promote with different fan strengths different volumes of air (120) through the air duct (102) in the area to be ventilated (122); and

- A time interval of the times of the sequence of times depends on the fan strength.

9) evaluation unit (101) according to one of the preceding claims, wherein the

 ventilating area (122) is the interior of a multi-lane vehicle.

10) evaluation unit (101) according to one of the preceding claims, wherein the

 Evaluation unit (101) is arranged to cause information relating to the occupancy state (202) of the air filter (107) to be output to a user of the ventilation system (100).

11) aeration system (100), which comprises

 - An air channel (102);

 an air filter (107) arranged to receive a number and / or quantity of

 To reduce particles in the air (120) in the air duct (102);

 a particle sensor (111) disposed in the air channel (102) and configured to detect particle sensor data indicative of the number and / or amount of particles in the air (120) in the air channel (102) having passed through the air filter (107); and

 - An evaluation unit (101) according to one of the preceding claims.

12) A method (300) for determining an occupancy state (202) of an air filter (107) of a ventilation system (100); wherein the ventilation system (100) is adapted to convey air (120) through an air duct (102) into a region (122) to be ventilated;

 wherein the ventilation system (100) in the air duct (102) comprises the air filter (107) and a particle sensor (111); the method (300) comprising

- determining (301) from the particle sensor (111) particle sensor data indicating a number and / or amount of particles in the air (120) in the air passage (102) that has passed through the air filter (107); and - determining (302), based on the particle sensor data and on the basis of characteristics (203) with respect to a particle separation efficiency (201) of the air filter (107), the occupancy state (202) of the air filter (107).