WO2003000386A1 - Passenger compartment adsorption filter with cyclic regeneration for motor vehicles - Google Patents

Abstract

The invention relates to a method for purifying the air entering the passenger compartment of vehicles. The device adsorbing the air impurities is regenerated at time intervals by desorption in built-in state. In an embodiment involving particularly simple technical equipment, available components such as heat exchangers and blowers can be used for desorption. In an arrangement that is particularly favorable from an energy viewpoint, the waste heat of the engine is used for desorption.

Description

Adsorption cabin filter with cyclic regeneration for motor vehicles

Description:

Adsorption cabin filters are known for use in motor vehicles for cleaning the supply air. Currently, they are already being used as standard in some vehicles. Common cabin filters consist of a particle filter, often in combination with an activated carbon filter, which is used to remove gaseous air contaminants (e.g. hydrocarbons, odors, nitrogen oxides, etc.). These adsorption cabin filters are used to remove high-boiling hydrocarbon compounds and odors from the ventilation air.

These filters are usually installed in the supply air duct of the ventilation system. The adsorber filters are usually replaced at regular intervals (e.g. at the inspection intervals).

Activated carbon filters are known to adsorb a number of gaseous air pollutants. The molecules are attached to the surface of the activated carbon. The absorption capacity of the filter therefore results from the available free inner surface of the adsorbent. The more mass of adsorbent available, the greater the amount of air pollution that can be absorbed.

As is known, the adsorption of air pollution is determined by the sorption equilibrium between the concentration in the air on the one hand and the loading of the adsorbent (i.e. the concentration of pollutants on the activated carbon) on the other hand. A certain loading X of the adsorbent is in equilibrium with a certain concentration c of the air pollution the air. As is well known, the sorption equilibrium is largely influenced by temperature. Low temperatures favor the adsorption, higher temperatures disadvantage the adsorption and favor the reverse process, the desorption, in which the already adsorbed air contaminants are released again from the surface of the adsorbent and can thus get back into the air.

The operating conditions of the activated carbon filter are subject to very strong fluctuations, the effects of which on adsorption have so far been insufficiently considered in this application.

• The temperatures in the vehicle are subject to very strong weather-related fluctuations. This affects both seasonal fluctuations and fluctuations depending on the time of day. Daytime fluctuations are particularly pronounced in the warm season. While the temperature can drop to low values at night, temperatures of up to 80 ° C can be reached in the stationary vehicle during the day in strong sunlight.

• The weather-dependent fluctuations in air humidity are superimposed on it. The relative humidity of the supply air can reach almost 100% in warm, humid weather.

• There are also strongly fluctuating conditions with regard to the concentrations of air pollution in the supply air.

The adverse effects of these fluctuating operating conditions will be discussed later.

A further limitation of the adsorber filters results from their limited loading capacity. This is limited for the following reasons: • The use of adsorbent in the form of a bed would offer a high adsorption capacity, but such a bed shows a large pressure loss in the flow. In the present application, the use of a bed is ruled out because of the too high required power of the ventilation blower

• The use of activated carbon fibers is usually excluded for cost reasons

• Fiber material coated with activated carbon is therefore often used. However, the amount of adsorbent that can be applied is low. As a result, the loading capacity of these activated carbon filters is also low

• Since the pressure drop through the entire arrangement must not be significantly increased, the size and mass of the adsorber are also limited

• The limited mass of the adsorbent inevitably entails only a relatively low loading capacity

In the case of the activated carbon filters that have become technically known, the filters are replaced at certain intervals (e.g. during vehicle inspections)

This has the following disadvantages: the usual long replacement intervals result in progressive loading of the activated carbon filter. The loading capacity of the adsorber filter can be exceeded for certain substances. As a result, these substances are no longer or at least not completely absorbed by the adsorber filter high boiling point and in the case of odorous substances, the adsorption causes at least some cleaning at the usual exchange intervals

In contrast to the known state of the art for substances with a high boiling point, it was found that for substances with a low boiling point (e.g. gaseous hydrocarbons) the cleaning by adsorption already subsided after a short period of time. To remove these substances from the supply air, the Adsorber filters can be replaced after significantly shorter periods

In addition, the loading of the activated carbon filter also depends on the concentration of air pollution in the inlet air. For frequent journeys in heavily used environments (eg tunnels or city centers), it may therefore be necessary to change the adsorber filter more often

Replacing the filters at short intervals, however, leads to significant additional costs, especially since the exchange is usually carried out by a specialist workshop

Further disadvantages of previously used activated carbon filters result from the following points of view

• In order to ensure desorption-free operation, the activated carbon filters may only be loaded up to a low load. A further, higher load is possible under certain conditions, but desorption can then take place under certain conditions (eg at higher temperatures in the vehicle)

• The maximum permissible load for desorption-free operation is limited, among other things, by the maximum temperature occurring in the vehicle

In addition, continuous absorption of the pollutants is not guaranteed throughout the entire application interval. The reason for this can be seen from the following consideration of the adsorption conditions

• In the new, unloaded condition, the activated carbon filters will have a good adsorption of air pollution

• After some operating time, the activated carbon filter will be partially loaded. After a longer operating time, due to the sorption balance and whose temperature dependence the effect depends on the ambient conditions

Air pollutants that have been adsorbed at low temperatures can, for example (due to the temperature-dependent sorption equilibrium) desorb at higher temperatures and thus get back into the indoor air

The following example may explain this in the morning at low temperatures when driving in city traffic (higher concentration of air pollutants) the air pollutants are adsorbed on the activated carbon filter.At the low temperatures, the activated carbon filter can clean the air pollutants down to low concentrations The interior of the vehicle can reach temperatures of up to 80 ° C. Depending on the position of the activated carbon filter in the air supply, similar temperatures can also occur in the activated carbon filter.At these temperatures, the sorption equilibrium is much less favorable, and desorption is favored (especially when the activated carbon filter is loaded) Already adsorbed air contaminants are released again from the surface of the activated carbon filter and thus get into the indoor air. Under unfavorable conditions, the concentrate can The air pollution in the snow room is significantly higher than if there were no activated carbon filter at all. With increasing operating time and increasing loading of the activated carbon filter, this process will occur more frequently

In the previously known arrangements of activated carbon filters, this effect can only be reduced by a large size of the activated carbon filter or by a very frequent replacement of the activated carbon filter

A further disadvantageous process can occur in the case of particularly high atmospheric humidity. At relative atmospheric humidity above 80%, the fine pores of the activated carbon filter required for the adsorption can be completely occupied by water molecules (so-called capillary condensation). In this case, the fine pores are no longer available for the adsorption of the air contaminants Grouting On the one hand, this significantly reduces the capacity of the activated carbon filter, and, on the other hand, displacement desorption of air contaminants that have already been adsorbed can also take place

The previous versions show that previous adsorption filters - especially with advanced loading - can rather be regarded as smoothing filters. At high concentration peaks the pollutants are absorbed by the filter, at low concentrations and especially at high temperatures the already adsorbed pollutants can be released into the air again become

Due to the described processes, the use of such activated carbon filters has so far been unsatisfactory, at least for the removal of pollutants with a low boiling point (e.g. gaseous air pollution)

In order to avoid the necessary frequent replacement of the adsorber filter, designs have recently become known in which the adsorber filter is freed of the absorbed pollutants by regeneration

A disadvantage of these designs is that the regeneration must be carried out outside the vehicle when removed. This results in similar restrictions as when changing the adsorber filter

The previously known versions with regeneration in the installed state have the disadvantage of a high additional energy requirement, which results from the electrical heating of the adsorber filter, as a rule

Another disadvantage of these solutions is the sometimes considerable additional expenditure on equipment, which makes practical use considerably more expensive The object of the invention is to develop an arrangement with which the activated carbon filter can also operate reliably over a long period of time. According to the invention, this object is achieved as follows

An adsorber is used for the adsorption, which in a first embodiment can be constructed like a conventional adsorber or activated carbon filter. The full adsorption performance of this adsorber is ensured by targeted desorption at certain intervals. The invention has the further object of providing this desorption with the least possible additional equipment and effort To carry out with the least possible additional energy expenditure According to the invention, this object is achieved as follows

• In the simplest arrangement, the desorption is carried out by rewinding the adsorber. Air from the interior can be used through the existing ventilation blower (which, however, has to change its direction). This can be heated to desorption temperature in the heat exchanger also available for the vehicle heating. This is low desorption is possible with additional equipment

• The least additional expenditure on equipment can be achieved if the adsorber is regenerated at specific intervals during downtimes of the motor vehicle by targeted desorption. The desorption is carried out by preheated air. In a particularly advantageous embodiment, the desorption air is heated in the heating register available for the vehicle heating Desorption can be carried out particularly effectively, with additionally pre-cleaned air

• Desorption can be carried out most favorably immediately after the vehicle has been parked. At this point, excess residual heat is available from the engine heat. In this case, the desorption air can be heated by the engine heat. The heat transfer can take place through the cooling water The desorption air is heated by the heat exchanger that is already provided for vehicle heating

In a further embodiment of the invention, the desorption air can also be heated by the engine heat, but the heat transfer is transmitted by 01 from the oil circuit of the engine. In this case, higher temperatures can be generated during the desorption. This enables an even more effective desorption to be carried out

• The blower can be arranged on the suction side, pressure side or between the individual devices

Arrangement of the adsorber

• In a particularly favorable arrangement, the adsorber — seen in normal air flow direction — is arranged in front of the heating register for the vehicle heater (FIG. 1 and FIG. 2). FIG. 1 shows the flow through the arrangement in normal vehicle ventilation. The air contaminants are adsorbed on the adsorber and thus the air is cleaned. The cleaned air can be heated in the heat exchanger and subsequently fed to the interior. FIG. 2 shows the circuit during regeneration of the adsorber. The air flows in the opposite direction through the arrangement. The air is first heated in the heat exchanger and then flows through the adsorber As a result, the adsorbent in the adsorber is heated and thus the desorption is initiated. The desorption air carries the air contaminants out of the adsorber

• In the simplest case, the desorption can then proceed as follows after parking the vehicle After parking the vehicle, a small air flow is sucked in from the interior by the existing blower (which, however, changes the direction of rotation for desorption). This air flow is then heated in the heat exchanger by the cooling water and then passed through the adsorber

The temperature of the cooling water of max. Approx. 110 ° C (with a slight overpressure in the cooling system) is sufficient for desorption.In many cases, the cooling water reaches its highest temperature immediately after the engine is switched off due to the lack of travel cooling, which in practical operation is caused by switching on the Radiator fan becomes clear

An advantage of this arrangement is the low outlay on equipment for the desorption circuit, since all components are already present. Only the blower must require a small amount of air in this operation with the direction of rotation reversed

In addition, with this arrangement it is avoided that preheated supply air is passed through the adsorber during heating operation. This ensures better adsorption

In the case of vehicles with air conditioning, it can be particularly advantageous to arrange the adsorber - seen in normal air flow direction - after the air cooler (heat exchanger of the refrigerant circuit) (FIG. 3)

In this case, cooled air is led through the adsorber in cooling operation. This has a favorable influence on the sorption balance. In this operation, the air pollution can be reduced to particularly low concentrations. This enables a particularly high air quality to be generated in the interior

A further advantage is that - especially in warm, humid weather - some of the air moisture condenses in the air cooler. Air with a lower water content is therefore passed through the adsorber, thereby reducing the accumulation of water in the pores of the adsorber

In combination with the preceding feature, a particularly favorable arrangement of the adsorber between the air cooler and the heat exchanger for vehicle heating results in vehicles with air conditioning (FIG. 4). FIG. 4 shows this arrangement of the adsorber between the heat exchanger of the cooling circuit and the heat exchanger of the heating circuit

In this case, the advantages of the two aforementioned features can be combined

If - seen in the direction of flow - a heat exchanger is arranged after the air cooler, but before the adsorber, the air can be partially heated again after the moisture has condensed out, which reduces the relative humidity of the air. This further reduces the adsorption of water in the adsorber (Fig. 5) Fig. 4 shows this arrangement of an additional heat exchanger between the air cooler and the adsorber

Heating the desorption air

• As described above, the desorption air is heated in the existing heat exchanger by the hot cooling water of the engine and then passed through the adsorber

In another embodiment, the desorption air can be heated in a heat exchanger by oil from the oil circuit of the engine. This enables higher temperatures to be generated for the desorption

• Alternatively, the desorption air can be heated by an electric heater. In this case, a higher temperature of the desorption air can be reached In an energetically favorable combination, the desorption air can first be heated in the existing heat exchanger by the hot cooling water or by the hot 01 of the engine and then further heated by an electric heater and then passed through the adsorber (Fig. 6 and Fig. 7) In this case, a higher temperature of the desorption air can be achieved by the additional electrical heating, while at the same time energy is saved by preheating by the cooling water or by the 01 FIG. 6 shows such an arrangement of an additional electrical heating of the desorption air in the ventilation operating mode; FIG. 7 shows one such an additional electrical heating of the desorption air in the regeneration mode (desorption)

In a further advantageous embodiment of the invention, the adsorber can be in a heat-conducting connection with a heat exchanger which is heated by cooling water or 01 In this case, heat is also transferred directly to the adsorbent. As a result, not all of the heat has to be transferred through the desorption air Design of a smaller desorption air flow This means that an even smaller blower output is sufficient (see Fig. 17 20)

desorption

• In the simplest arrangement, the desorption air can be sucked in from the interior

• Alternatively, the desorption air can be drawn in from the outside air via a separate line

• If outside air is sucked in, it can be cleaned by a small upstream adsorber (Fig. 8 and Fig. 9)

• This adsorber for the desorption air can be desorbed again in normal driving by rinsing with cleaned and possibly heated interior air (Fig. 10)

8, 9 and 10 show an exemplary arrangement of the suction of the desorption air from the outside air and the cleaning of this desorption air by an additional desorption air adsorber. In normal ventilation operation (FIG. 8), the additional desorption air adsorber does not need to be flowed through, FIG. 9 shows the circuit during the regeneration of the main adsorber. Outside air is sucked in, cleaned in the desorption air adsorber, then heated in the heat exchanger, if necessary further heated in an additional electric heater and passed through the adsorber, this being regenerated (desorbed) in certain The additional desorption air adsorber must then be regenerated at intervals. The circuit for this is shown in FIG. 10

The arrangements in FIGS. 8 to 10 only show exemplary arrangements. The additional desorption air adsorber can, for example, also be arranged in a circuit without additional electrical heating. It is also possible for part of the air to be regenerated during the regeneration of the additional desorption air adsorber (FIG. 10) lead to the interior and use only the other part of the air for the desorption of the additional desorption air adsorber. In addition, the opening of the desorption air suction line can be controlled by an additional flap Promotion of desorption air:

• The desorption air can be conveyed by the existing fan, provided that this is designed for backward conveying.

• Alternatively, the desorption air can be conveyed by a separate fan. This can be useful for conveying small amounts of desorption air. This arrangement can be particularly useful in connection with an electric heater.

Control of the regeneration cycles:

• In the simplest case, desorption takes place at regular intervals after the vehicle has been parked. In the simplest case, certain time intervals can be specified for the desorption. After this interval, the desorption is carried out automatically the next time the vehicle is parked.

• Desorption could also be requested manually for special requirements or when driving through particularly polluted air. In this case, a desorption cycle is carried out after the next parking of the vehicle.

• Alternatively, the concentration of air pollution can be measured with a sensor. The use of a sensor to determine the breakthrough of the adsorber would be conceivable, but not necessarily useful, since such an operating state is to be avoided at all.

It is cheaper e.g. measure the concentration of air pollution in the incoming ambient air. From this and from other data, e.g. The temperature and the humidity of the incoming air or the temperature of the adsorber, the temperature of the cooling water and the time since the last desorption can then be used to calculate optimized regeneration cycles. This control has the advantage that e.g. Different regeneration cycles can be calculated in summer than in winter. In addition, by simply evaluating this data, the desorption cycles can be adapted to different climatic conditions.

Another advantage of these measurements is that desorption e.g. can be carried out if the ambient air is particularly lightly contaminated. By using this slightly polluted ambient air, the desorption air does not need to be cleaned beforehand.

• When the desorption air is heated via the cooling water, the desorption cycle can be limited by the temperature of the cooling water and by the amount of heat stored.

In this case, a controller can calculate the regeneration state reached from the desorption temperature and the desorption time and use this to determine the next regeneration interval.

• In the above In cases (with heating by the cooling water) desorption should take place immediately after parking the vehicle, as long as the cooling water is still at its high operating temperature. A logic circuit can prevent desorption if the ventilation is switched on when the vehicle is stationary.

• Under particularly unfavorable conditions, desorption according to the above Executions can also be carried out while driving. In this case, however, the vehicle ventilation and the vehicle heating are not available during this desorption time.

• A particularly convenient design is described under the keyword "two-channel adsorber". Regeneration during operation of the vehicle is possible. With this arrangement, the control cycles described above can trigger the desorption of a channel even while driving

Two channel adsorber

Only a short service life is expected for the continuous adsorption of volatile substances.Therefore, desorption cycles must be carried out at relatively short intervals.For vehicles that are used a lot (e.g. vehicles used for business purposes, taxis, etc.), it can make sense to enable desorption while driving In the aforementioned arrangements, this is possible in principle, but then no ventilation of the vehicle can take place during the desorption. With the embodiments described below, a simultaneous sequence of desorption and vehicle ventilation and vehicle heating can be achieved

Another variant is the use of two separate adsorbents. This corresponds to the use of clocked adsorbers or of rotor adsorbers in process engineering applications. The desorption of one adsorber can take place while the other adsorber is in operation. However, the disadvantage is the considerably greater equipment outlay

• In order to reduce the additional outlay on equipment, it is possible in particular to arrange an adsorber in each of the two separate channels (eg left and right) of the vehicle ventilation or air conditioning. If such a separate heating / air conditioning system is already available in the vehicle (eg in vehicles of the higher classes) , so at least some of the required components (heat exchanger and possibly also blower) are available for both ventilation ducts anyway.If an adsorber is integrated in each of the two ventilation ducts, separate adsorption and desorption can be implemented in a relatively simple manner Although there is limited functionality of the respective ventilation duct during the desorption of one of the adsorbers, the additional outlay in terms of equipment is very low. Desorption can also take place at a time when the ventilation of the second duct is not required anyway

• In the case of the above-mentioned design, the design is such that, in the normal state, both adsorbers can be operated in parallel. When the regeneration interval expires, one of the adsorbers is then desorbed, while the other adsorber continues to operate. After desorption of one adsorber, the other becomes Adsorber desorbed (Fig. 11, Fig. 12, Fig. 13) Fig. 11 shows the two-channel adsorber with separate ventilation channels in the ventilation mode. The circuit for the regeneration of channel 1 is shown in Fig. 12 The circuit for the regeneration of channel 2 is analogous Fig. 13 shown In the arrangements shown here by way of example, each of the two channels has its own blower. Arrangements with only one blower are also possible, the flow of the air being controlled via flaps

• In addition to the above-mentioned design for a restricted adsorption (eg only with a reduced amount of air) during the desorption time of one of the two adsorbers, a solution with two full-fledged adsorbents can also be carried out in a more complex arrangement. However, this requires separate air guidance and the respective switching of the Air flows over flaps (Fig. 14, Fig. 15, Fig. 16) Fig. 14 shows this two-channel arrangement in the ventilation mode, recognizable by the position of the flaps shown in Fig. 14 Fig. 15 shows the arrangement in the regeneration mode of duct 2 Fig. 16 shows the analog arrangement in the regeneration mode of channel 1

The desorption of the adsorber in channel 2 is described using the example of FIG In this arrangement shown by way of example in FIG. 15, outside air is sucked in by the blower, passed through the damper position on channel 1, cleaned there in the adsorber, then heated in channel 2 in the heat exchanger and passed through the adsorber in channel 2, whereby this adsorber is channeled in channel 2 desorbed Due to the drawn flap position, this desorption air is then released into the environment

With this arrangement it is also possible to supply a partial flow of the air cleaned in duct 1 to the interior via the flap leading to the interior and to use only the remaining air flow for the desorption of duct 2. This option is not shown The ratio of the air quantities between the air leading to the interior and the air used for the desorption of the channel 2 can be set via the degree of the opening of the flap

An additional advantage of this two-channel adsorber solution is that purified air is available for the desorption

Another advantage results from the fact that cooling water of the same temperature is always available during the journey. Thus, the desorption cycle is not limited in time, but can also take place over a longer period of time

Material of the adsorber

• Another advantage of the solution according to the invention is the lower required mass of adsorbent due to the desorption at shorter intervals. This means that more expensive adsorbents (eg hydrophobic zeolites) can be used. When using such materials, the absorption of water can be ruled out even at high relative air humidity

Device for heating the adsorbent

• The air for desorption of the adsorber can be heated in a heat exchanger as described in the above-mentioned embodiments and then fed to the adsorber. The adsorbent in the adsorber is heated by the hot air, which leads to desorption

• It can be advantageous if the adsorbent is heated not by the air but by its own heat source. In this case, the adsorbent is heated independently of the air flow and in particular independently of the air volume. This means that the desorption can also be carried out with a smaller air flow

This can be done, for example, by arranging the adsorbent in heat-conducting contact with a heat source. As shown by way of example in FIG. 17, the heat source can consist of a hollow body through which a heat transfer medium, for example cooling water or motor oil, flows. FIG. 17 is an example a possible execution

A heat-conducting contact with a heat source can also take place by arranging the adsorbent in contact with heat-conducting elements, which in turn are in heat-conducting contact with a heat source.This also results in a heat flow between the heat source and the adsorbent a heat source through which a heat carrier flows, heat-conducting plates (ribs) arranged thereon and adsorbent arranged between these plates Fig. 19 shows another exemplary arrangement, in which in the manner of a

Heat exchanger fins are applied to pipes by a

Heat carriers are flowed through, and the adsorbent is located between the ribs.

FIG. 20 shows a further exemplary embodiment in which the heat source has an electrical heater.

Claims

Expectations 1 method for cleaning the incoming indoor air from vehicles with at least one air pollution adsorbing device in particular adsorbing filter, characterized in that the adsorbing device can be regenerated in the installed state at intervals by desorption of the absorbed air pollution 2 The method according to claim 1, characterized in that the adsorbing device is designed especially for cleaning the supply air of volatile gases and vapors 3 The method according to claim 1, characterized in that the adsorbing device is arranged fixed in the air duct of the vehicle ventilation and contains no moving parts 4 The method according to claim 1, characterized in that a separate adsorbing device is arranged in separate ventilation guides of the vehicle 5 The method according to claim 1 to 4, characterized in that the regeneration of the adsorbing device is carried out by backwashing with air 6 The method according to claim 1 to 5, characterized in that the regeneration of the adsorbing device is carried out by backwashing with heated air 7 The method according to claim 1 to 6, characterized in that the desorption air for regeneration through existing ventilation channels from the direction of the interior in the direction of the previous air supply 8 The method according to claim 1 to 7, characterized in that for the regeneration operation, the air guidance takes place in existing air guidance systems and the air demand for regeneration takes place by changing the direction of the existing blower 9. The method according to any one of claims 1 to 8, characterized in that the desorption air for regeneration is heated in a heat exchanger, the heat being supplied by the cooling water of the engine 10 The method according to any one of claims 1 to 9, characterized in that the desorption air for regeneration is heated in a heat exchanger already present for the vehicle heating, the heat being supplied by the cooling water of the engine 11 The method according to any one of claims 1 to 6, characterized in that the desorption air is heated for regeneration in a heat exchanger, the heat being supplied by oil, for example from the engine or transmission of the vehicle Method according to one of claims 1 to 6, characterized in that the desorption air for regeneration is heated by an electric heater. Method according to one of claims 1 to 11, characterized in that the desorption air for regeneration is first heated in a heat exchanger and subsequently with an electric heater is heated to a higher temperature. Method according to one of claims 1 to 13, characterized in that the adsorbent is in heat-conducting contact with a switchable heat source. Method according to one of claims 1 to 13, characterized in that the adsorbent is arranged on or in a carrier is in heat-conducting contact with a switchable heat source. Method according to claim 14 or 15, characterized in that the switchable heat source consists of a housing which can be flowed through with a heat-carrying medium, preferably water or oil ren according to claim 14 or 15, characterized in that the switchable heat source consists of a heat exchanger through which a heat-carrying medium, preferably water or oil, can flow. Process according to claim 17, characterized in that the adsorbent is arranged in a heat exchanger 16 or 17, characterized in that the heat-carrying medium is part of the cooling water circuit of the engine or part of an oil circuit of the vehicle. Method according to one of claims 14 or 5, characterized in that the heat source consists of an electric heating element. Method according to one of claims 1 to 19 characterized in that the demand for desorption air for regeneration by a blower is carried out according to one of claims 1 bιs21 characterized in that the demand for desorption air for regeneration is carried out by the ventilation blower used for vehicle ventilation and the This is designed for a possible backward demand method according to one of claims 1 to 22, characterized in that the desorption air for regeneration is sucked in from the interior of the vehicle. Method according to one of claims 1 to 23, characterized in that the desorption air for regeneration by a separate line is sucked in with a A method according to claim 24, characterized in that the desorption air is cleaned by a Regeneπerluft adsorber arranged in the Regeneπerluft line. The method according to Claim 24, characterized in that the Regeneπerluft adsorber arranged in the line is again ventilated by purging with cleaned and or heated indoor air The process according to one of the preceding claims is characterized in that the adsorbing device - viewed in the direction of the air flow - is arranged in front of the heating heat exchanger. The process according to one of the preceding claims is characterized in that the adsorbing device - viewed in the direction of the air flow the heat exchanger of the refrigerant circuit is arranged method according to one of the preceding claims, characterized in that an additional heat exchanger between the heat exchanger of the refrigerant circuit and the adsorbing device Method is arranged according to one of the preceding claims, characterized in that the adsorbing device - viewed in the direction of the fresh air flow - is arranged after the blower. Method according to one of the preceding claims, characterized in that the regeneration of the adsorbing device takes place during downtimes of the vehicle one of the preceding claims, characterized in that the regeneration of the adsorbing device takes place immediately after the vehicle has been switched off. Method according to claim 32, characterized in that the residual heat still present after the engine has been switched off is used to heat the desorption air. Method according to one of claims 1 to 33 characterized in that separate adsorbent devices are alternately regenerated in separate ventilation guides of the vehicle. Method according to claim 34, characterized in that the separate adsorbent devices n devices are alternately regenerated during driving operation. Method according to one of the preceding claims, characterized in that the regeneration of the adsorbing device takes place at regular time intervals. Method according to one of the preceding claims, characterized in that the regeneration of the adsorbing device takes place at time intervals, which are carried out by means of a controller or a program can be calculated from measured operating data Adsorbing device, in particular adsorbing filter for carrying out the method according to one of claims 1 to 37, characterized in that the adsorbent is arranged between heatable surfaces of a heat exchanger. Adsorbing device, in particular adsorbing filter for carrying out the method according to one of claims 1 to 37, characterized in that that the adsorbent is arranged on or in a carrier and is arranged together with this between the heatable surfaces of a heat exchanger. Adsorbing device, in particular adsorbing filter for carrying out the method according to one of claims 1 to 37, characterized in that heatable surfaces of the heat exchanger are coated with adsorbent are adsorbing devices, in particular adsorbing filters for carrying out the method according to one of the preceding claims, characterized in that the adsorbing device contains activated carbon adsorbing Device, in particular adsorbing filter for carrying out the method according to one of the preceding claims, characterized in that the activated carbon is introduced in the form of fiber materials. Adsorbing device, in particular adsorbing filter for carrying out the method according to one of the preceding claims, characterized in that the adsorbent a porous support, for example a foam, a fibrous structure, a honeycomb structure or arranged on parallel plate-like walls Adsorbing device, in particular adsorbing filter for carrying out the method according to one of the preceding claims, characterized in that the adsorbent is arranged on parallel-oriented plate-like walls with a profiled surface. Adsorbing device, in particular adsorbing filter for carrying out the method according to one of the preceding claims, characterized that the adsorbent forms a honeycomb structure. Adsorbing device, in particular adsorbing filter for carrying out the method according to one of the preceding claims, characterized in that the adsorbent forms parallel-oriented plate-like walls with a profiled surface