WO2019091755A1 - System for exhaust-gas treatment for a motor vehicle, method and device for determining a state of a system for exhaust-gas treatment for a motor vehicle - Google Patents

Abstract

The invention relates to a system for exhaust-gas treatment for a motor vehicle having: a first exhaust-gas treatment element (101), a second exhaust-gas treatment element (102), a common housing (103), in which the first exhaust-gas treatment element (101) and the second exhaust-gas treatment element (102) are arranged, an antenna (104) for transmitting and/or receiving microwaves (116) into the housing, a microwave filter (105) having a specified pass frequency, which microwave filter is arranged in the housing (103) between the first exhaust-gas treatment element (101) and the second exhaust-gas treatment element (102) such that microwaves (116) of a first frequency (106) emitted by the antenna (104) are reflected by the microwave filter (105) and microwaves (116) of a second frequency (107) emitted by the antenna (104) pass through the microwave filter (105), the first frequency (106) being less than the pass frequency and the second frequency (107) being greater than or equal to the pass frequency.

Description

description

A system for exhaust gas treatment for a motor vehicle, method and apparatus for determining a condition of a system for exhaust gas treatment for a motor vehicle

The application relates to a system for exhaust gas treatment for motor vehicles. The application further relates to a method for determining a condition of a system for exhaust gas treatment for a motor vehicle. In addition, a device is provided which is designed to carry out a corresponding method.

Motor vehicles with gasoline or diesel internal combustion engines or gas engines require various components for exhaust aftertreatment in order to comply with the statutory emission limits. These include, inter alia, the three-way catalytic converter, the diesel oxidation catalyst, the nitrogen oxide storage catalytic converter, the SCR catalytic converter (selective catalytic reduction), the diesel and Otto particle filter and other elements. Several elements can also be combined, for example an SCR coating particulate filter (SDPF).

It is desirable to provide a system for exhaust gas treatment for a motor vehicle, that a reliable operation it ^¬ made possible. In addition, it is desirable to provide a method for determining a condition of a system for exhaust gas treatment for a motor vehicle, which enables a reliable determination. Furthermore, it is desirable to provide a device that allows reliable detection.

According to at least one embodiment, to a system for exhaust gas treatment for a motor vehicle a first Abgasbe ^¬ treatment element. The system has a second exhaust gas acting element on. The system includes a common housing by disposing the first exhaust treatment element and the second exhaust treatment element. The system includes an antenna for transmitting and / or receiving microwaves in the housing. The system has a microwave filter with a predetermined pass frequency. The microwave filter is disposed in the housing. The microwave filter is arranged between the first exhaust gas treatment member and the second Abgasbehand ^¬ lung element, so that light emitted from the antenna microwaves of a first frequency of the microwave filter are reflected. Microwaves of a second frequency emitted by the antenna are transmitted through the microwave filter. The first frequency is less than the pass frequency. The second frequency is greater than or equal to the

Pass frequency. For example, the pass frequency is 2 GHz. Other pass frequencies are possible.

The first and the second exhaust gas treatment element is in each case in particular a filter and / or a catalyst of an exhaust gas treatment system of the motor vehicle, also called Abgasnachbe ^¬ treatment system. For example, the filter is a particulate filter, in particular a soot particle filter. Alternatively or additionally, the exhaust gas treatment element is a catalyst, for example an oxidation catalyst

Three-way catalyst, a NOX storage catalyst, a

HC adsorber for minimizing hydrocarbon emissions and / or a further element for the treatment of exhaust gases of an internal combustion engine of the motor vehicle. In order to determine the state of the exhaust gas treatment element, electromagnetic waves in the microwave range are coupled into the housing. The frequencies of the microwaves are, for example, in a range between 300 megahertz and some 100 gigahertz. The metallic housing provides an electrical Cavity resonator. In response to the transmitted wave, a frequency spectrum is recorded either in reflection and / or in transmission and / or by means of time domain reflectometry. The properties of the spectrum change with a change in the dielectric constant in the housing. The change of

Dielectric constant is determined by a change in Leitfä ^¬ ability and / or losses or a microwave attenuation and / or a change in the quality factor Q and / or a change in the resonant frequency and / or a phase change. If, for example, soot particles are deposited in a filter, a change in the received microwaves is also detectable.

Electromagnetic properties inside the enclosure are affected by material changes or material inputs. The incorporation of molecules or particles in the exhaust gas treatment element leads to a higher polarization and attenuation and thus to a higher half-width, lower frequency, quality factor Q and amplitude and a change in phase and duration of the wave.

Even a higher temperature leads to lower frequencies due to the thermal expansion of the housing. However, this can be compensated with the aid of models, for example by means of software. Also, other measurement parameters can be combined for analysis with operating parameters of the vehicle, in ^¬ play, an ambient temperature, a humidity, a signal one gas sensor such as a lambda probe and / or a NOx sensor, a load condition of a catalyst and / or filter.

The system includes the first and second exhaust treatment elements in the common housing. For example, the first exhaust treatment element is an SCR catalyst disposed downstream of a diesel particulate filter with SCR coating is. The microwave filter separates the common housing into two areas. The microwave filter is, for example, a high-pass filter. Electromagnetic waves can only propagate from certain frequencies and can only penetrate the microwave filter at certain frequencies. For example, the microwave filter is designed as a grid, in particular metallic grid or perforated plate. The size of the gaps or holes in the micro wave ^¬ lenfilter sets the transmission frequency. For example, the smaller the holes in the microwave filter, the larger the transmission frequency. A rejuvenation in the housing or in the exhaust system as a microwave filter is possible.

If the first frequency is less than the transmission frequency, the microwave filter for the propagation of the microwaves becomes like a closed metallic wall. Once the frequency of the microwaves is greater than the transmission frequency, so for example, has the second frequency, the Mir ^¬ kowellenfilter for example, acts as a disturbance. The microwaves, however, can penetrate the microwave filter and also propagate behind it.

The arrangement of the microwave filter between the two exhaust ^¬ treatment elements allows a separate diagnosis of both exhaust treatment elements in a single common

Casing. The antenna is located, for example, in the region of the first exhaust gas treatment element. The first exhaust treatment ^¬ element and the antenna are arranged for example on a common side of the microwave filter. Thus, the antenna and the first exhaust treatment element are in a ge ^¬ common resonance chamber. At the first frequency below the pass frequency, it is possible to diagnose a condition of the first exhaust treatment element. The microwaves do not reach the area of the housing by arranging the second exhaust treatment element.

Only at higher frequencies is the second exhaust gas treatment element achieved by the microwaves. A condition of the second exhaust treatment element may be measured. For this it is necessary, for example, to take into account the condition of the first exhaust gas treatment segment. Thus, it is possible to play at ^¬ to measure using a single antenna in a single housing both the loading of the SCR catalyst with NH3 and the soot charge in a particulate filter.

In accordance with at least one embodiment, the system has a further antenna for transmitting and / or receiving microwaves. The microwave filter is disposed between the antenna and the other antenna.

Thus, an exhaust gas is provided per exhaust treatment element. Thus, it is in particular possible to examine both exhaust gas treatment elements even at low frequencies below the transmission frequency. Also, the state of the second exhaust element can be determined, for example, with a third frequency. The third frequency is in particular smaller than the transmission frequency. The measurement with lower frequencies allows in particular a higher accuracy at lower loads. Detection of NH3 is also possible. Alternatively or additionally, ash detection after regeneration is possible. In addition, it is possible to measure the entire resonance space within the housing at high frequencies in transmission. In this case, one antenna serves to transmit the microwaves and the second antenna to receive the microwaves. This allows high accuracy, for example, for high quiet loads in the par- microfilters with strong attenuation, which can not be measured sufficiently accurately in reflection.

In accordance with at least one embodiment, the system includes third and fourth antennas for transmitting and / or receiving microwaves in the housing. The antenna and the third antenna are disposed on a common side of the microwave filter, and the further antenna and the fourth antenna are disposed on a common side of the microwave filter facing the antenna side and the third antenna side. The microwave filter is disposed between the antenna and the other antenna. It is also possible to arrange two antennas on one side of the microwave filter and only one antenna on the other side.

Thus, it possible to examine the first and / or second Abgasbehand ^¬ development element both in transmission and in reflection. The transmission measurement is also possible in sub-segments of the housing. In accordance with at least one embodiment, the system has a

Plural n of exhaust treatment elements on. The exhaust elements are arranged side by side in the common housing. The system has a plurality n-1 of microwave filters. The microwave filters each have mutually different transmission frequencies. A respective microwave filter of the plurality of microwave filters is arranged between two exhaust gas treatment elements of the plurality of exhaust gas treatment elements. In particular, starts at the antenna of the microwave ^¬ filter, which has the smallest transmission frequency. Each subsequent microwave filter then has a higher transmission ^¬ frequency than its predecessor. The farther from the antenna, the higher the transmission frequency. The system allows the determination of the states of any number of exhaust gas treatment elements in succession, separated by under ^¬ schiedliche microwave filter by means of a single measurement system ^¬ with the antenna.

According to a further aspect, a method for determining a state of a system for the exhaust gas treatment for a motor vehicle is specified and a corresponding front ^¬ direction, which is designed to perform the method. The system includes a first exhaust treatment element and a second exhaust treatment element disposed in a common housing.

In accordance with at least one embodiment, microwaves of a first frequency are emitted into the housing. Microwaves of a second frequency are emitted into the housing. The first frequency is less than the second frequency. Microwaves are received in response to the broadcast. The condition of the first exhaust treatment element is determined in response to microwaves received in response to the transmission of the first frequency microwaves. The condition of the second exhaust treatment element is determined in response to microwaves received in response to the transmission of the second frequency microwaves. This is done, for example, taking into account the state of the first Abgasbehand ^¬ development elements.

At lower frequencies, the microwaves do not propagate to the second exhaust treatment element. Thus, it is possible to determine the state of the first exhaust gas treatment element, although in the housing also the second exhaust gas treatment element is arranged. ₀

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Only at higher frequencies do the microwaves reach the second exhaust gas treatment element. Thus, it is possible to determine the state of the second exhaust treatment element. In accordance with at least one embodiment, the microwaves of the first frequency are reflected before the microwaves of the first frequency reach the second exhaust gas treatment element. In particular, the microwave ^filter is provided for this purpose. In accordance with at least one embodiment, to determine the state of the second exhaust-gas treatment element, first of all a mixed state of the two exhaust-gas treatment elements is determined. The mixing condition is determined in response to the microwaves received in response to the transmission of the second frequency microwaves. The state of the second exhaust gas treatment member is determined on the basis of the mixing state in dependence from ^¬ by the microwaves, which are received in response to the emission of the microwaves of the first frequency. The microwaves of the second frequency spread out throughout the housing and thus respond to both the first exhaust ^¬ treatment element and to the second exhaust treatment ^¬ element. Consequently, a change in only one of the components results in a change of the mixing state, without first of all recognizing which of the exhaust-gas treatment elements a change has occurred. The exhaust gas treatment elements in the housing are measured at once and the changes in the properties of the individual exhaust gas treatment elements are superimposed.

To determine the state of the second coupling member Abgasbehand ^¬ from the mixing state, the microwaves are considered, which are below the pass frequency. Thus, in particular, a state of the first exhaust treatment element "

 y known. This information is used to calculate the influences of the first exhaust gas treatment element from the mixed state. From the mixed state containing information about the first exhaust gas element and the second exhaust gas element, it is thus possible to filter the information about the state of the second exhaust gas treatment element.

In accordance with at least one embodiment, the state of the first and / or the second exhaust gas treatment element is measured in reflection or transmission as a function of the type of the respective exhaust gas treatment element. For example, a measurement of soot loading of a particulate filter is more accurate in transmission than in reflection, especially when the particulate filter is heavily loaded. For example, the determination of the state of a catalyst is more accurate when the reflection of the emitted microwaves is evaluated. A time domain reflectometry (TDR) is also possible.

In accordance with at least one embodiment, the system has a plurality n of exhaust gas treatment elements. Microwaves with n different frequencies are emitted. A respective state of the exhaust gas treating element is a respective frequency of the frequencies determined in depen ^¬ dependence. In particular, the microwaves are gradually reflected below predetermined transmission frequencies, whereby the transmission frequencies become monotonically smaller.

Further advantages, features or developments emerge from the following examples explained in conjunction with the figures. The same, similar and equivalent elements may be provided with the same reference numerals therein. Show it:

1 shows a schematic representation of a system according to an embodiment,

FIG. 2 shows a schematic representation of a system according to an embodiment,

Figure 3 is a schematic representation of a system according to an embodiment, and

Figure 4 is a schematic representation of a system according to an embodiment. FIG. 1 shows a system 100 for exhaust gas treatment for motor vehicles. The system 100 is in particular a Abgasnachbe ^¬ treatment system of a motor vehicle or part of such a system. Exhaust gas 114 from an internal combustion engine not explicitly shown is introduced into the system 100. In the system 100 exhaust treatment elements 101, 102 are arranged. These serve, for example, to purify the exhaust gas 114 of emissions.

The first exhaust gas treatment element 101 and the second exhaust gas treatment element 102 are each a filter, in particular a particulate filter such as a soot particle filter for diesel and / or Otto internal combustion engines, a catalyst, a combination of a catalyst and a particulate filter, a three-way catalyst, an oxidation catalyst

NOX storage catalyst, an ammonia slip catalyst and / or other elements to reduce emissions in the exhaust 114. The first exhaust gas treatment element 101 and the second exhaust ^¬ treatment element 102 are arranged in a common housing 103rd The housing 103 is in particular a metallic housing and forms an electrical cavity resonator.

An antenna 104 is provided to emit and receive microwaves 116 within the housing 103. The antenna is, for example, a coaxial pin coupler. The antenna 104 is in particular a high-frequency antenna which is coupled to a corresponding activator, such as an Os ^¬ zillator. The coupling can be done electrically and / or inductively.

During operation, substances accumulate in the first exhaust treatment element 101 and in the second exhaust treatment element 102, for example, soot in a particulate filter and ammonia in an SCR catalyst. The loading state of the respective exhaust gas treatment element 101, 102 is determined, for example, using high-frequency measurement technology, in particular with the microwaves 116. The microwaves are, for example, in a range between 300 megahertz and a few 100 gigahertz. Other frequency ranges are possible.

By means of a single antenna 104, both the exhaust gas treatment member 101 as to be able to measure also the second exhaust gas treatment ^¬ element 102, a microwave filter is provided 105th The microwave filter 105 is disposed along the flow direction of the exhaust gas 114 between the first exhaust treatment member 101 and the second exhaust treatment member 102. The microwave filter 105 has a predetermined pass frequency. Microwaves having a first frequency 106 that is less than the pass frequency are not transmitted by the microwave filter 105, but reflected or absorbed. Microwaves with a second frequency 107, the greater than or equal to the transmission frequency, pass through the microwave filter 105 therethrough. The microwave filter 105 is, for example, a metallic grid or a perforated plate. The size of the distances in the grid or the size of the holes, for example, the transmission frequency is predetermined. Alternatively or additionally, the passage frequency is predetermined by the selection of the material of the microwave filter 105. Alternatively or additionally, a targeted taper of the cross section of the housing 103 is provided, which is designed so that it is a microwave filter 105. A combination of different elements is possible.

In operation, for example, first microwaves 116 are radiated at the first frequency 106 and received in reflection again from the antenna 105. The microwaves 116 with the first

Frequency 106 propagate only in the region of the first exhaust treatment element 101, since they can not transmit through the Mikrowel ^¬ lenfilter 105. Within the housing 103, a resonance space for the first exhaust gas treatment element 101 is thus formed. For example, the first exhaust ^¬ treatment element 101 is an SCR catalyst. By means of the Mik ^¬ rowellen 116 at the first frequency 106 is a load condition of the SCR catalyst is determined. To determine the state of the second exhaust gas treatment element 102, microwaves 116 with the second frequency 107 are emitted by the antenna 104. These pass through the microwave filter 105 into the region in which the second exhaust gas treatment element 102 is arranged. The second exhaust gas treatment element 102 is, for example, a filter, in particular a soot particle filter. This has, according to embodiments, a coating, such as an SCR coating. By means of the microwaves 116, play determines a soot loading of the second coupling member Abgasbehand ^¬ 102nd

For example, the state of the second exhaust gas treatment element 102 is determined directly from the reflection of the microwaves 116 at the second frequency 107. This is particularly possible if the influences of the loading of the second exhaust gas treatment element 102 on the properties of the microwaves are significantly greater than the influences of the loading of the first exhaust gas treatment element 101. Consequently, the influences of the first exhaust gas treatment element 101 are negligible when the reflection of the microwaves 116 with the second frequency 107 is evaluated. According to further embodiments, the influences of the first exhaust gas treatment element 101 are calculated out of the reflections of the microwaves 116 with the second frequency 107. This is possible in particular because the influences of the first exhaust gas treatment element 101 from the measurement with the microwaves 116 with the first frequency 106 are known.

In order to evaluate the received microwaves and to determine the states of the exhaust gas treatment elements 101, 102, a ^device 117 is provided. The device 117 is part of an engine control of the motor vehicle, for example.

The microwave filter 105 within the housing 103 allows a loading determination of each exhaust gas treatment element 101, 102 that is disposed within the housing 103. It is not only possible to measure all the exhaust gas treatment elements 101, 102 within the housing 103 at once with superimposed analyzable resonance properties, but specifically by means of different frequencies above and below the

Passing frequency of the microwave filter 105 on the first Exhaust treatment element 101 and the second exhaust treatment ^¬ element 102 to close.

FIG. 2 shows the system 100 according to a further exemplary embodiment. In addition to the antenna 105 is another

Antenna 108 is provided to transmit and / or receive microwaves 116 in the housing 103.

The antenna 104 is disposed along the flow direction of the exhaust gas 114 on a first side of the microwave filter 105. The further antenna 108 is arranged on an opposite side of the microwave filter 105. The antenna 104 is arranged in ^¬ particular within a resonance chamber with the first Ab ^¬ gas treatment element 101. The further antenna 108 is arranged in particular within a common resonance space with the second exhaust gas treatment element 102. Thus, it is possible to emit by means of the further antenna 108 microwaves with a third frequency 112, which is below the passage frequency of the microwave filter 105. Thus, the loading state of the second exhaust treatment element 102 is directly measurable by the reflections of the third frequency 112 received by the further antenna 108 and subsequently evaluated. The third frequency 112 is, for example, equal to the first frequency 106 or different from the first frequency 106.

The system 100 according to the embodiment of Figure 2 it ^¬ enables thus a determination of the state of the first Ab ^¬ gas treatment element 101 and the second exhaust gas treatment element 102 separated from each other in reflection measurement. In addition, it is possible to perform a transmission measurement with microwaves of the second frequency 107. For example, the microwaves are emitted by the antenna 108 and received by the antenna 104. Depending on the condition of the exhaust treatment elements 101 and 102 and the nature of the exhaust treatment elements 101, 102, either a reflection measurement or a transmission measurement is performed. For example, a reflection measurement has a higher accuracy with lower soot loadings of a particulate filter, with ash detection after regeneration, with a detection of NH3 on an SCR coating of a filter and / or further states to be determined. A transmission measurement, for example, has a higher accuracy at high soot loadings, which result in a strong attenuation of the microwaves. For example, with strong attenuation, reflections can not be measured sufficiently accurately enough.

It is possible to diagnose at low frequencies only the respective Abgasbe ^¬ treatment element 101, 102 located on one side of the microwave filter 105 in reflection and to diagnose both exhaust treatment elements 101, 102 in transmission at higher frequencies. FIG. 3 shows the system 100 according to a further exemplary embodiment. Overall, the system has 100 according to the management from ^¬ example of Figure 3, a plurality n of Abgasbe ^¬ action elements. Shown are a third exhaust ^¬ treatment element 109 and the n-th exhaust gas treatment element 110. The plurality of n is preferably greater than 3 and for example less than 30. The n-gas treatment elements 101, 102, 109, 110 are all arranged within the common housing 103rd

In each case between two directly adjacent and adjacent exhaust gas treatment elements 101, 102, 109, 110 one of n-1 microwave filters is provided. Between the first exhaust gas treatment element 101 and the second Abgasbehand ^¬ averaging element 102 of the microwave filter 105 is provided. Between the second exhaust treatment element 102 and the third Exhaust treatment element 109, a second microwave filter 111 is provided. In the flow direction of the exhaust gas 114, a (nl) -term microwave filter 115 is provided in front of the nth exhaust treatment element 110.

The microwave filter 105, 111, 115 each have a different transmission frequency, so that only frequencies above the respective predetermined pass frequency spreading in ^¬ flow direction of exhaust gas 114 after each microwave filter 105, 111, 115 themselves.

Consequently, an n-th frequency 113 which is above the passage frequency of the last microwave filter 115 is present in the last resonance space of the nth exhaust treatment element 110 along the flow direction. All other frequencies 106, 107, 112 that are smaller than the pass-through frequency of the microwave filter 115 are filtered by the last microwave filter 115. Thus, with only a single antenna 104, it is possible to determine the exact state of each of the exhaust elements 101, 102, 109, 110, although they are disposed in the single common housing 103. It is also possible to provide more than one antenna in the exemplary embodiment of FIG. 3, for example the antenna 104 and one or more further antennas 108. Thus, similar to the exemplary embodiment of FIG. 2, both a ^reflection measurement and a transmission measurement are made possible.

FIG. 4 shows the system 100 according to a further exemplary embodiment. On the side of the microwave filter 105, on which the antenna 104 is arranged, a third antenna 118 is arranged. The antenna 104 and the third antenna 118 are disposed on both sides of the first exhaust treatment element 101. On the side of the microwave filter 105, on the other Antenna 108 is arranged, a fourth antenna 119 is arranged on ^¬ . The further antenna 108 and the fourth antenna 119 are arranged on both sides of the second exhaust gas treatment element 102. This makes it possible to determine the state of the first and / or second exhaust gas treatment element 101, 102 in each case with two

Antennas. Thus, the state of each exhaust treatment element 101, 102 can be determined both in transmission and in reflection. Also in the embodiment of FIG. 3, it is possible to provide two antennas per exhaust gas treatment element 101, 102, 109, 110. It is also possible to provide second antennas for one part of the exhaust gas treatment elements 101, 102, 109, 110, and only a single antenna for the rest of the exhaust gas treatment elements 101, 102, 109, 110.

Different combinations of the measurement of the antennas 104, 108, 118, 119 in transmission and reflection are possible.

For example, microwaves 116 emitted by the antenna 104 are received by both the third antenna 118 and the further antenna 108 after transmission.

The system 100 enables disposing a plurality Abgasbehand ^¬ coupling members 101, 102 in the single common housing 103. By means of the antenna 104 and, optionally, the device 117, it is possible due to the disposed in the housing 103 micro ^¬ wave filter 105, the properties and states of the exhaust gas treatment elements 101, 102 within the housing 103 separately to determine and evaluate. Thus, a separate diagnosis of the different exhaust treatment ^¬ elements 101, 102 is possible.

The microwave filter 105 separates the exhaust treatment elements 101, 102 with respect to microwaves that are within the Spread housing 103. With only a single antenna 104 is first measured within the resonance chamber of the first Abgasbehand ^¬ treatment element 101 with low frequency. The resonance space is limited by the housing 103 and the microwave filter 105. Within the resonant cavity is ge ^¬ measure in reflection. At higher frequency is measured within the entire housing 103 in reflection.

 By means of the two antennas 104 and 108, it is possible to measure the respective resonance spaces on both sides of the microwave filter 105 separately from one another. According to embodiments, any number of mutually different microwave filters 105 are arranged within the housing 103.

In particular, in the reflection measurement with only a single antenna 104 mathematical methods are applied according to embodiments in order to close on the individual segments and exhaust ^¬ treatment elements 101, 102. In particular with multiple antennas 104, 108, it is possible to measure in reflection and / or transmission and / or TDR. If more than one microwave filter 105 is provided, comprise microwave filters 105, 111, 115 have mutually different filter constants, ie in particular mutually different Durchlassfre ^¬ sequences. These are realized, for example, by holes of different sizes in the grid or perforated plate of the respective microwave filter 105, 111, 115.

Claims

claims A system for exhaust treatment for a motor vehicle, comprising: a first exhaust treatment element (101), a second exhaust treatment element (102), - a common housing (103), in which the first Abgasbe ^¬ treatment element (101) and the second exhaust gas treatment element (102) are arranged,  an antenna (104) for transmitting and / or receiving microwaves (116) into the housing,  - A microwave filter (105) with a predetermined Passage frequency, which is arranged in the housing (103) between the first exhaust treatment element (101) and the second exhaust treatment element (102), so that emitted from the antenna (104) microwaves (116) of a first frequency (106) are reflected by the microwave filter (105) and transmit microwaves (116) emitted by the antenna (104) of a second frequency (107) through the microwave filter (105), the first frequency (106) being smaller than the average frequency (106). and the second frequency (107) is greater than or equal to the transmission frequency. 2. System according to claim 1, wherein the microwave filter (105) has a grid and / or perforated plate and / or a taper of the housing (103). 3. A system according to claim 1 or 2, comprising a further antenna (108) for transmitting and / or receiving microwaves (116), wherein the microwave filter (105) between the antenna (105) and the further antenna (108) is arranged. 4. The system of claim 3, comprising - A third and a fourth antenna (118, 119) for transmitting and / or receiving microwaves (116) in the housing, wherein the antenna (104) and the third antenna (118) on a ge ^¬ common side of the microwave filter (105) are arranged, and the further antenna (108) and said fourth antenna (119) on a common side of the microwave filter (105) arranged are opposite to the side of the antenna (104) and the third antenna (118). A system according to any one of claims 1 to 4, wherein the first exhaust treatment element (101) comprises a filter and the second exhaust treatment element (102) comprises a catalyst. 6. System according to one of claims 1 to 5, comprising  a plurality n of exhaust gas treatment elements (101, 102, 109, 110) arranged side by side in the common housing (103),  - A plurality n-1 of microwave filters (105, 111, 115), each having mutually different transmission frequencies, wherein in each case a microwave filter (105, 111, 115) of the plurality of microwave filters (105, 111, 115) between two exhaust treatment elements (101 , 102, 109, 110) of the plurality of exhaust treatment elements (101, 102, 109, 110). 7. A method for determining a state of a system (100) for exhaust gas treatment for a motor vehicle, wherein the system (100) comprises a first exhaust treatment element (101) and a second exhaust gas treatment ^¬ element (102) arranged in a common housing (103) are,  Emitting microwaves (116) of a first frequency (106) into the housing, - emitting microwaves (116) of a second frequency (107) into the housing (103), the first frequency (106) being smaller than the second frequency (107), Receiving microwaves (116) in response to the broadcast, - Determining the state of the first exhaust treatment element (101) in response to microwaves (116) received in response to the transmission of the microwaves (116) of the first frequency (106), - Determining the state of the second exhaust treatment element (102) in response to microwaves (116) received in response to the transmission of the second frequency (107) microwaves (116). 8. The method of claim 7, comprising:  - Reflecting the microwaves (116) of the first frequency (106) before the microwaves (116) of the first frequency (106) reach the second exhaust treatment element (102). 9. The method of claim 7, wherein determining the state of the second exhaust treatment element includes: Determining a mixed state of both exhaust treatment elements (101, 102) in response to the microwaves (116) received in response to the emission of the microwaves (116) of the second frequency (107),  - determining the state of the second exhaust treatment element (102) from the mixing state in response to the microwaves (116) received in response to the transmission of the first frequency microwave (106). 10. The method according to any one of claims 7 to 9, comprising: - Determining the state of the first and / or second exhaust treatment element (101, 102), depending on the nature of the j eweiligen exhaust gas treatment element (101, 102) in reflection or transmission. 11. The method of claim 7, wherein the system comprises a plurality n of exhaust gas treatment elements, comprising: Emitting microwaves (116) with n different frequencies (106, 107, 112, 113), - Determining a respective state of the exhaust treatment ^¬ elements (101, 102, 109, 110) as a function of each frequency (106, 107, 112, 113) of the frequencies (106, 107, 112, 113). 12. Device which is adapted to perform a method according to any one of claims 7 to 11.