WO2020200611A1 - Air filter device for a motor vehicle and motor vehicle having same - Google Patents

Abstract

The invention relates to an air filter device (101) for a motor vehicle, having at least one ionization unit (102) for generating electrons (13), through which unit an air stream (103) to be purified can flow; a separating unit (104), which is arranged downstream of the ionization unit (102), for generating an electric attractive force, by means of which electrons (13) generated by the ionization unit (102) can be deposited on the separation unit (104), wherein an area through which air can flow of all ionization units (102) together is greater than 150% of an area through which air can flow through of the separation unit (104).

Description

Air filter device for a motor vehicle and motor vehicle with such

The invention relates to an air filter device with an ionization unit and a separation unit and a motor vehicle with such a unit

Air filter device.

Currently, the cabin supply air, which is a passenger compartment of a

Motor vehicle is supplied, cleaned by means of particle and / or activated carbon filters of particles, pollutants or harmful gases. In addition, electrostatic filters are known from the area of air cleaners for buildings or from industrial areas (flue gas cleaning) to remove dust and

To remove ultra-fine dust from an air stream. However, such electrostatic precipitators are difficult to use in vehicles because there are significantly higher requirements in terms of installation space and volume

treating air flow exist.

FIG. 1 shows schematically an electrostatic filter 1 with an ionization unit 2 through which an air stream 3 to be cleaned flows and generates the electrons that adhere to particles in the air stream 3. Downstream a separation unit 4 is arranged, in which the particles in the air flow 3, due to the electrons adhering to them, to the

Adhere the separation unit 4.

FIG. 2 schematically shows the basic principle of an electrostatic filter 1. The air stream 3 with particles 5 first flows through the ionization unit 2. The ionization unit 2 has a discharge plate 6, which in turn has a multiplicity of air passage openings 7 (for example round)

having webs 8 located therebetween. In addition, the ionization unit 2 has a pin plate 9, which in turn has pins 10, between which air passage openings 11 are formed. Tips 12 of the pins 10 extend towards the discharge plate 6 and / or into the air passage openings 7 and generate electrons which are electrically attracted by the positively charged discharge plate 6. More precisely, the electrons migrate from the tips 12 to the edges of the

Air passage openings 7 of the discharge plate 6. Some of the electrons 13 adhere to particles 5 on the way from the tips 12 to the discharge plate 6, for example, along paths 13 through the

Air passage openings 11 flow. These particles with adhering electrons are provided with reference number 14 downstream of the ionization unit 2 and flow through the separation unit 4 downstream of the ionization unit 2. This has negatively charged plates 15 and positively charged plates 16. As they flow through the separation unit 4, the particles 14 are attracted by the positively charged plate 16 due to their adhering electrons, are electrostatically bound and thus remain in the separation unit 4, more precisely on the plate 16, and adhere there.

The disadvantage of an electrostatic filter, as shown in FIGS. 1 and 2, is that the cleaning efficiency is not sufficient in the motor vehicle sector. Due to the installation space and the high volume flows required in vehicle air conditioning, the efficiency of such electrostatic filters in vehicles is significantly lower than in the domestic and industrial sector. It is therefore an object of the present invention to at least partially eliminate the aforementioned disadvantages. This object is achieved by an air filter device according to claim 1 and a motor vehicle solved according to claim 9. Advantageous further developments of the invention are the subject matter of the dependent claims.

According to an embodiment of the invention, a

Air filter device provided for a motor vehicle, with at least one ionization unit for generating electrons through which an air stream to be cleaned can flow; a separation unit, which is arranged downstream of the ionization unit, for generating an electrical attractive force by means of which electrons generated by the ionization unit can be deposited on the separation unit, wherein a

The flowable area of all ionization units together is greater than 150% of a flowable area of the separation unit. In particular, the ionization units, in the case of several ionization units, are not arranged in series, i.e. the air flow cannot flow through them one after the other, but are arranged in parallel. Because the flow-through face of the ionization unit is significantly larger than the flow-through face of the separation unit, a higher one can be achieved

Electrostatic charging of particles in the air flow (i.e. more electrons adhere to the particles in the air flow) can be achieved, which in turn leads to more reliable adhesion of the electrostatically charged particles in the separation unit. As a result, better cleaning of the air flow is achieved overall.

According to a further embodiment of the invention, the

Air filter device designed such that a

Main plane of extent of the at least one ionization unit, in which the ionization unit has its greatest extent, of one

The main expansion plane of the separation unit, in which the separation unit has its greatest extent, differentiates. This alignment enables the flow through face of the ionization unit compared to the

to enlarge through-flow ble area of the separation unit significantly. This enables the advantages mentioned above to be achieved. According to a further embodiment of the invention, the

Air filter device designed in such a way that two ionization units are provided which are arranged in a triangular shape together with the separation unit, the separation unit forming one leg of the triangle and the two ionization units forming the other two legs of the triangle. Such an arrangement makes it possible to enlarge the area of the ionization unit through which flow can flow

at the same time keep the required installation space as small as possible.

According to a further embodiment of the invention, the

Air filter device designed such that the downstream air

Separation unit is arranged a filter having activated carbon. This filter can be used to filter out any ozone components that may be present from the air flow before it is directed into the passenger compartment.

According to a further embodiment of the invention, the

Air filter device designed such that the ionization unit has a discharge plate with air passage openings and a pin plate with air passage openings on which discharge pins are arranged, the tips of which extend to or into the air passage opening (s). According to a further embodiment of the invention, the

Air filter device designed such that the smaller value of a sum of the areas of the air passage openings of the discharge plates and a sum of the areas of the air passage openings of the pin plate forms the flowable area of the at least one ionization unit. According to a further embodiment of the invention, the

Air filter device designed such that the separation unit in

Having plates running in the direction of flow.

According to a further embodiment of the invention, the

The air filter device is designed in such a way that the surface of the separation unit that can be flowed through is formed from the sum of the flowable surfaces between the plates.

The present invention also provides a motor vehicle having such an air filter device.

A preferred embodiment of the present invention is described below with reference to the accompanying drawings. These drawings show:

Figure 1 shows schematically an electrostatic filter from the prior

Technology;

Figure 2 shows schematically the basic principle of an electrostatic

Filters; and

Figure 3 shows schematically an embodiment of a

air filter device according to the invention.

FIG. 3 schematically shows a filter device 101, in particular an electrostatic filter, according to an exemplary embodiment of the present invention. The filter device 101 has one or more

Ionization units 102, which electrostatically charges particles (for example dusts or fine dusts) contained in an air stream 103 flowing through the ionization unit 102, so that this filter device 101 is deposited. The structure of the ionization unit 102 can for example, correspond to the structure of the ionization unit 2 shown in FIG. 2 with a discharge plate 6 and a pin plate 9, so reference is made to the description of the ionization unit 2 at this point. It is also possible to use a structure for the ionization unit 102 in which the electrons are emitted by spray wires instead of pins. In this case, instead of the discharge plate with air passage openings, several plates extending in the air flow direction would be provided, which form the ground poles. In addition, the filter device 101 has a separation unit 104, which filters out the electrically charged particles, which are contained in an air flow 117 downstream of the ionization unit 102, from the air flow 117. This takes place according to the principle described in FIG. 2 in connection with separation unit 4. With regard to the structure of the separation unit 104, the description of FIG

Separation unit 4 according to FIG. 2 can be referred to.

An air flow 118 leaving the separation unit 104 is an air flow cleaned by the filter device 101, which is downstream of the

Filter device 101 flows through a filter 119 having activated carbon.

In contrast to the prior art, for example as shown in FIG. 1, the ionization unit 101 has a significantly larger one

flowable surface than that from Figure 1, which means that the particles can be electrostatically charged more reliably.

For example, the filter device 101 can have two ionization units 102 and a separation unit 104, which are arranged in the form of a triangle, the separation unit 104 being one leg of the

Forms triangle and the two ionization units 102 form the other two legs of the triangle. A wall can be provided between the two ionization units 102. Between two neighboring ones Legs, for example, an angle of 60 ° is included. Instead of the two ionization units 102, a single correspondingly curved or angled ionization unit 102 can also be used. Other arrangements are also conceivable. For example, an ionization unit 102 can be used, which is aligned essentially parallel to the separation unit 104 (similar to FIG. 1), but has a larger flowable area than the separation unit, which means that the housing of the filter device extends downstream of such an ionization unit tapered to the separation unit. Likewise, a trapezoidal arrangement could be used in which the

The wall between the two ionization units 102 from FIG. 3 is replaced by a cover running essentially parallel to the separation unit 104, so that overall a trapezoidal shape is created. The flow-through face of the ionization unit 101 is determined by the flow-through face face of the discharge plate 6 or the flow-through face face of the pin plate 9, depending on which is the smaller of the two areas. The flow-through face of the discharge plate 6 is the sum of the areas of the air passage openings 7 of the discharge plate 6. The flow-through face of the pin plate 6 is the sum of the areas of the air passage openings 11 of the pin plate 6. In the case of

Separation unit 6, the flowable area is the sum of the

flow through ble surfaces which are formed between the plates 15, 16.

According to the invention, a flowable area of the ionization unit is greater than 150% of a flowable area of the separation unit. In particular, a flowable area of the ionization unit is greater than 170% of a flowable area of the separation unit.

In particular, a flowable area of the ionization unit is greater than 200% of a flowable area of the separation unit. While the invention is detailed in the drawings and in FIG

As illustrated and described above, this description is to be regarded as illustrative or exemplary in nature, and not as restrictive, and it is not intended to limit the invention to the embodiment disclosed. The mere fact that certain features are mentioned in different dependent claims is not intended to indicate that a combination of these features could not also be used to advantage.

Claims

Expectations 1. Air filter device (101) for a motor vehicle, comprising: at least one ionization unit (102) for generating Electrons (13) through which an air stream (103) to be cleaned can flow; a separation unit (104), which is arranged downstream of the ionization unit (102), for generating an electrical force of attraction by means of which electrons (13) generated by the ionization unit (102) can be deposited on the separation unit (104), wherein a flowable area of all ionization units (102) together is greater than 150% of a flowable area of the Separation unit (104). 2. Air filter device (101) according to claim 1, wherein a Main expansion plane of the at least one ionization unit (102), in which the ionization unit (102) has its largest expansion, from a main expansion level of the separation unit (104), in which the Separation unit (104) has its largest dimension differs. 3. Air filter device (101) according to one of the preceding Claims, wherein two ionization units (102) are provided which are arranged in a triangle together with the separation unit (104), the separation unit (104) forming one leg of the triangle and the two ionization units (102) forming the other two legs of the triangle. 4. Air filter device (101) according to one of the preceding Claims, wherein a filter (119) having activated carbon is arranged downstream of the airflow from the separation unit (104). 5. Air filter device (101) according to one of the preceding Claims, wherein the ionization unit (102) has a discharge plate (6) with air passage openings (7) and a pin plate (9) Has air passage openings (11) on which discharge pins (10) are arranged, the tips (12) of which to or into the / Extend air passage openings (11). 6. Air filter device (101) according to claim 5, wherein the smaller value of a sum of the areas of the air passage openings (7) of the Discharge plates (6) and a sum of the areas of the Air passage openings (11) in the pin plate (9) form the surface of the at least one ionization unit (102) which can be flown through. 7. Air filter device (101) according to claim 5 or 6, wherein the separation unit (104) has plates (4) extending in the direction of flow. 8. Air filter device (101) according to claim 7, wherein the flow-through face of the separation unit (104) is formed from the sums of the flow-through ble areas between the plates (15, 16). 9. Motor vehicle with an air filter device (101) according to one of claims 1 to 8.