FR2976856A1 - AUTOMOBILE AIR SUPPLY DEVICE AND METHOD OF REGENERATING A GAS FILTER OF THE DEVICE - Google Patents

Abstract

A device (1) for the supply of cabin air to a motor vehicle with electric or hybrid propulsion, equipped with a power supply battery (2), comprises a gas filter (3) and a resistor (6). ) heating able to heat the filter (3) or to heat the air arriving on the filter (3) for its regeneration. The device (1) comprises an electronic control unit configured to activate the heating resistor during a vehicle stopping step where the battery (2) is in the electric charging stage from an external network (20) to the vehicle.

Description

BACKGROUND OF THE INVENTION The present invention relates to the field of supplying air to a passenger compartment of a motor vehicle, and in particular to the field of supplying air to a passenger compartment of a motor vehicle. filtering the air taken outside the vehicle entering the passenger compartment, particularly in the case of a vehicle with an air-conditioning supply system. The invention relates more particularly to a device and a method for the regeneration in situ on the vehicle of an air filter, in particular an activated carbon type gas filter, which can be equipped with the packaging systems. of air for a motor vehicle. Activated charcoal gas filters use activated granular activated carbon, or in the form of fibers constituting the filter, activated carbon to adsorb and retain gaseous pollutants that would otherwise enter the cabin and cause an olfactory discomfort or sanitary for the occupants of the vehicle. Once the polluting molecules are adsorbed on the activated carbon, the filtering efficiency of the latter decreases rapidly. It is then necessary to either change the filter or regenerate the activated charcoal by operations allowing it to release the adsorbed molecules. These activated carbon filters can be part of combined filters comprising an active carbon layer intended to capture the gaseous pollutants, and a layer of material capable of filtering the particles of small size (typically, the particles of the order of ten microns). Both types of filter layers can be integrated within the same filtering texture. Particle saturation of the filter is gradual, and sufficient efficiency can be maintained by changing the filter about every 30,000 kilometers. On the other hand, the active carbon of the filter, because of the reduced quantities of coal present, in order to limit the cost and the weight of the device, leads to a much faster saturation of the available active carbon.

Since the phenomenon of retention of gaseous pollutants by activated carbon is reversible, periodic regeneration operations can be envisaged. This regeneration can for example be carried out by subjecting the filter to an air stream of sufficiently high temperature. The polluting molecules can then be desorbed and evacuated by the regeneration air flow. Depending on the type of filter used, generally comprising active carbon in the form of powder, agglomerates, granules or fibers, the heating of the coal or of the air which sweeps it may be provided by an upstream device, or by a electrical resistance embedded in the filter, or by passing electrical current through even the activated carbon so as to form a conductive network. The document FR 2 744 375 proposes a device for automatic regeneration of activated carbon filter comprising electrical resistances arranged upstream of the filter, and whose energization is synchronized with a reversal of the direction of air circulation in the passenger compartment. The device makes it possible to reject the air containing the polluted desorbed products to the outside. These desorption phases are periodically performed during a start of the vehicle, while purging certain channels of the air conditioning system. Such a device has the disadvantage of being a consumer of electrical energy, which, in the case of a heat engine vehicle, increases its fuel consumption, and in the case of a vehicle with electric propulsion, reduces the fuel consumption. autonomy of it. Patent application FR 2 848 500 proposes an automatic charcoal filter regeneration device in which the reversal of the direction of air circulation occurs after stopping the vehicle, the engine being still warm and the air being heated by passage in a heater containing the still hot liquid of the engine cooling circuit. The effectiveness of such a device varies according to the amount of heat stored in the engine cooling system. In addition, this system is activated by drawing on a battery of the vehicle the energy necessary for the flow of air and possibly the flow of water from the cooling circuit in the heater. This energy is not compensated before the next driving of the vehicle, which, depending on the case, can reduce the efficiency of starting the vehicle if it is driven by a heat engine, or can reduce the autonomy of the vehicle for a vehicle with electric propulsion. The purpose of the invention is to propose a device for regenerating a filter, in particular a vehicle activated carbon filter, which makes it possible to increase the efficiency of the regeneration phase without encroaching on the electrical energy reserve. available during the next taxi. Another object of the invention is to use the regeneration phase to improve the olfactory comfort of passengers beyond the mere regeneration of the activated carbon filter, especially in the case of a vehicle with electric propulsion or a hybrid powered vehicle. To this end, a passenger compartment air supply device of a motor vehicle with electric or hybrid propulsion, equipped with an electric supply battery, comprises a gas filter and comprises a heating resistor able to heat the filter. or to heat air arriving at the filter during a regeneration phase of the filter. The device includes an electronic control unit configured to activate the heating resistor during a vehicle stopping step where the battery is in the electric charging stage from a network outside the vehicle. Preferably, the device comprises an electronic unit for managing the current delivered to the battery terminals during recharging of the battery, which modifies the current delivered during the regeneration phases of the filter, with respect to the current delivered outside the regeneration phases. Advantageously, the device comprises a gas filter and comprises one or more controlled flaps adapted to channel an air flow through the filter towards the interior of the passenger compartment in a first mode of ventilation operation, and capable of channeling a air flow through the filter from the passenger compartment to the outside of the vehicle in a second mode of regeneration operation. The device further comprises electrical means for heating the incoming air to the filter in the second regeneration mode, or for heating the filter itself, and comprises an electrically driven pulsator for causing the first and second flow directions. of air, respectively corresponding to the first and second operating mode. The device comprises an electronic control unit configured to actuate the blower, the shutters and the electric heating means in regeneration mode, during a step of stopping the vehicle where the battery is in the phase of electric recharging from a network outside the vehicle. The electric heating means may for example comprise an electrical heating resistor, or may comprise an electric pump capable of circulating heated cooling liquid through a heater. Advantageously, the device comprises a status counter for evaluating an elapsed time and / or a mileage traveled since the last regeneration phase, and a validating unit authorizing a new regeneration phase if the time or the mileage is greater than a predefined threshold. , and if a recharge phase of the battery on the external network has been activated for a validation threshold duration.

The device may also include a presence estimator, which only allows the triggering of a regeneration step if all the occupants have left the vehicle. The device may further include a vehicle condition estimator, which allows initiation of a regeneration step only if the vehicle is being reloaded into an open space. According to a preferred embodiment, the electrical resistance or the heating means of the device comprise a resistor which also makes it possible to heat the air of the passenger compartment in a mode of operation distinct from the regeneration mode, or comprise resistive wires integrated into the device. filtered. According to an advantageous embodiment, the device comprises, among the heating means, an electric pump for circulating water of a cooling circuit through a heater during the regeneration phase. Preferably, the device comprises an air conditioner whose evaporator is interposed in the path of the air circulating during the regeneration phase between the passenger compartment and the outside of the vehicle.

Advantageously, the evaporator is, during the regeneration, downstream of a heating means of the air flow used for the regeneration, for example downstream of the resistance. According to a preferred embodiment, the device comprises an activated carbon filter with integrated resistive wires, which during the regeneration phase is upstream on the air flow with respect to the evaporator. According to another embodiment of the invention, the evaporator is, during the regeneration, upstream of the filter to be regenerated. The control unit can be connected to a humidity sensor, and can be configured to compare the sensor measurement with a humidity threshold in order to decide whether or not to close the regeneration phase. It is thus possible to extend the regeneration phase until a satisfactory level of drying of the evaporator and / or the filter has been obtained.

In another aspect, a method of regenerating a motor vehicle passenger compartment filter comprises a step in which a specific air flow is activated, from the passenger compartment to the outside of the vehicle, through the filter, and in which resistive heating means is activated during a recharging phase of a vehicle battery from an electrical network outside the vehicle. According to a preferred embodiment, these activations are done after performing a verification procedure to consider that all occupants of the vehicle have left it.

The present invention will be better understood on studying the detailed description of some embodiments taken by way of non-limiting examples, and illustrated by the accompanying drawings, in which: FIGS. 1a and 1b illustrate a feeding device in the air according to the invention, - Figures 2a and 2b illustrate another air supply device according to the invention, - Figures 3a and 3b illustrate another air supply device according to the invention, - the figure 4 illustrates a method according to the invention for regenerating a device for supplying air to a passenger compartment of a motor vehicle. In Figure 1, a device 1 for supplying air to a motor vehicle is shown schematically in vertical section along the longitudinal direction of the vehicle. There is thus diagrammatically a front cover 14 and a water box 16 of the vehicle, arranged in front of a windshield 15 of the vehicle. The air supply device 1 comprises a set of pipes 17 in which an air flow can be caused by a blower 5 of the centrifugal fan type. The direction of air circulation and / or the flow rates in the various pipes can be modified by means of a set of shutters comprising in particular a mixing flap 11, a distribution flap 12 and a bypass flap 13.

The air supply device 1 also comprises an air conditioning system of which only the evaporator 4 is shown here. The device also comprises a heater 7 for exchanging calories between the air circulating in the passenger compartment and a cooling liquid used to remove calories from a battery and / or a vehicle engine. The device finally includes a resistance 6 to bring additional calories to the air of the cabin, in case the calories available at the level of the heater are insufficient. The resistor 6 may for example be a CTP (positive temperature coefficient) type resistor, that is to say a thermistor whose resistance increases strongly with temperature over a limited temperature range (typically between 0 ° C. and 100 ° C.). VS).

The blower 5 and the resistor 6 are powered by a battery 2 of the vehicle which is intended to be recharged regularly from an electrical network outside the vehicle, for example a motor power supply battery of an electric-powered vehicle or of a hybrid-powered vehicle.

A filter 3 is disposed in the path of at least one pipe 17 of the feed device 1, this filter 3 containing a pollutant capture element capable of being regenerated by a flow of hot air, for example containing coal active. Activated carbon is a material with a high surface area due to the presence of many pores and is able to adsorb polluting gases. Once a certain amount of gas has been adsorbed, the capture efficiency of the activated carbon decreases. It is then possible to regenerate the active carbon by sweeping it by a flow of hot gas, for example by a gas of temperature between 50 and 90 ° C, which causes the desorption of a portion of the gaseous pollutants, which the we then try to evacuate to the outside of the vehicle. The principle is of course applicable to other materials having the same adsorption property of certain gaseous species, this adsorption being variable with temperature. The filter 3 can be a combined filter, that is to say a filter having, in addition to an active carbon layer capable of capturing polluting and gaseous species, one or more layers capable of filtering particles, of size for example included between 0.5 and 10 μm.

In the example of FIG. 1a, the filter 3 can be traversed by an electric current delivered by the battery 2, to which it is connected by connections 18. According to the variants, the filter 3 can for example be heated by wires resistive added inside the structure of the filter, or by a current directly through the activated carbon network made conductive. In Fig. La, the device is illustrated in the normal vehicle air supply configuration, for example when the vehicle is traveling. The arrows in mixed dotted line represent the path of the air flows in the device. In the configuration of FIG. 1a, the air outside the vehicle enters through an air inlet 8 located here at the water box, is directed by the blower 5 through the filter 3, then passes on the evaporator 4 of the air conditioning system, which can be cold if the air conditioning is running, so as to give up cold air to the incoming air. After passing on the evaporator 4, part of the air can pass under a mixing flap 11, then through successively the heater 7 and the resistor 6. Depending on the position of the mixing flap 11, the rest of the flow passes above the mixing flap 11 without exchanging calories with the heater or with the resistance. For this, as illustrated in Figure la, a bypass flap 13 is in a horizontal position, so as to allow this air flow to pass under the mixing flap 11. Depending on the position of the mixing flap 11, a more or less significant proportion of the flow arriving through the filter 3 can therefore pass above the mixing flap 11. The greater this proportion, the more air in the cabin will be cool, or the more it will remain at room temperature if the air conditioning is active. The two flows arriving above and below the mixing flap 11 then meet at a distribution flap 12. Depending on the position of the distribution flap 12, a greater or lesser proportion of the resulting flow is sent to different parts of the vehicle, for example to the windshield 15 or to the driver's feet (not shown).

FIG. 1b illustrates the feed device of FIG. 1a, in regeneration configuration of the filter 3. In FIG. 1b, the vehicle containing the device 1 is at a standstill, and its battery 2 is connected by connections 19 to an entry point of an external electrical network 20 (shown as a single-phase supply network at 200V, but which could for example be a three-phase network, or another type of network). An electronic control unit ("ECU", not shown) manages the charging procedure of the battery 2. In the case where the connection point 20 to the external network already delivers a direct current, CHIP can for example manage the intensity of the current allowed to enter through the battery terminals. If the connection point 20 to the external network supplies an alternating current, CHIP can furthermore handle the rectifying and filtering procedure of the current, between the external network and the terminals of the battery. The electronic control unit is also configured to manage the air supply of the passenger compartment, as well as regeneration steps of the filter 3. To this end, CHIP is able to modify the positions of the different flaps 11, 12, 13 , the speed of rotation of the blower 5, and the heating power of one or more resistive elements of the passenger compartment, such as the resistor 6. It may also be able to actuate a pump for circulating coolant in a cooling circuit connected to the heater 7.

Under certain conditions, the electronic control unit puts the air supply device in regeneration configuration of the filter 3, as shown in FIG. In this configuration, the blower 5 induces a flow of air from the interior of the passenger compartment to the filter 3 and then to the outside of the vehicle, the air inlet 8 being closed. At the same time, the internal heating system of filter 3 is activated. The air thus heated in contact with the resistive elements of the filter 3 causes the desorption of a portion of the pollutant gases, then passes on the surface of the evaporator 4. The evaporation of the evaporator 4 in the hot air flow from of the filter 3 causes the evaporation of residual moisture which may have condensed on the evaporator 4 after an air conditioning cycle for bringing frigories to the air of the passenger compartment. The energy required for heating the filter 3 and the operation of the blower 5 is taken at the terminals of the battery 2 by the connections 18. Depending on the amount of energy required for the regeneration, and depending on the amount of energy available to from the external network, the regeneration energy is therefore taken entirely on the external network, or is taken partly on the external network, and partly on the battery. In the second case, the recharging time of the battery is extended in a minimal way to obtain the same final charge, and the vehicle can then leave without its autonomy is affected. Note that in the case where the reloading is done from a non-continuous current network, the filtering process may involve the value of the current arriving at the terminals of the battery, which in our case is different from the value of the current. current entering the battery. In a preferred embodiment, so that the regeneration energy is taken entirely on the external network, without affecting the charging process of the battery, CHIP can be configured to allow a current arriving at the terminals of the battery, which takes into account not only the needs of the battery, but these needs increased by the intensity of the current required for regeneration.

The bypass flap 13 and the mixing flap 11 each occupy a position which prohibits the return of polluted air polluting species to the interior of the passenger compartment. The position of the bypass flap 13, on the other hand, makes it possible to evacuate this air via a condensate evacuation channel 10 which serves, during stops of the vehicle not accompanied by a regeneration of the filter 3, to allow the flow by gravity of condensed moisture on the evaporator 4. The distribution flap 12 is in turn in a position preventing the return to the passenger compartment of the air taken from the passenger compartment by the blower 5.

It will be noted that in this embodiment of the invention, the integrated heating system filter 3 is placed upstream of the evaporator 4 during the regeneration process, which makes it possible to heat the air directly at the level of the filter and Moreover, in the air supply mode as in the regeneration mode, the air passes through the filter before passing on the evaporator, which makes it possible to improve the drying of the evaporator 4. allows for example to avoid deposits of dust (particles) on the evaporator.

Figure 2a illustrates, still in longitudinal section of the vehicle, another embodiment of the invention. FIG. 2 shows elements that are common to FIGS. 1a and 1b, the same elements being designated by the same references. In the embodiment of FIG. 2a, the filter 3 is devoid of internal heating means and is placed at the level of the air inlet 8 in the passenger compartment located at the level of the water box 16. normal ventilation mode illustrated in Figure 2a, for example when the vehicle rolls, the air enters the device through the filter 3, is then directed on the evaporator 4 by the blower 5, is divided into two streams passing the l one above the mixing flap 11, the other below the mixing flap 11.The flow passing below the mixing flap 11 passes through the heater 7 and then the resistor 6. The resistor 6 can be supplied with electric current by the battery 2 through connections 23. Downstream of the heater 7, the resulting stream, optionally cooled by the evaporator 4 and / or heated by the heater 7 and / or the resistor 6 is then distributed in the different parts of the passenger compartment by pipes 17, in proportion variable in different parts of the passenger compartment according to the positions of the distribution flap 12. A flap 22 helps to channel a portion of the air flow from the flap 12 to the inner face of the windshield 15. Figure 2b illustrates the device of Figure 2a in filter regeneration mode 3. The vehicle is stopped, the battery 2 is connected to an electrical network by a connection point 20. The position of the different flaps 11, 12, 21, 22 is this time modified so that the air stirred by the blower 5 is taken by a recycled air inlet 9 on the passenger compartment, then sent on the evaporator 4, then directed under the mixing flap 11, in order to pass through the heater 7 and the resistor 6, then to be discharged to the outside through the filter 3. In this configuration the flap 22 returns to the air inlet 8 the airflow coming from the flap 12. It should be noted that in this configuration, the evaporator 4 is unique air swept to the air temperature of the passenger compartment, and not by preheated air. This moist air then passes through the heater 7, which allows it to be heated "free" by the coolant present in the heater at the time of stopping the vehicle. Depending on the case, the electronic control unit can be configured to actuate an electric pump circulating the cooling liquid inside the cooling circuit connected to the heater, so as to benefit for the heating of the air regeneration, all the calories stored in the cooling circuit. In order to increase the efficiency of the heating, the electronic control unit is configured to trigger a heating of the resistance 6. The hot and humid air thus obtained is sent outside the passenger compartment through the filter 3. Compared to the embodiment of Figure lb, the filter 3 is crossed by an air that is already hot on arriving at the filter, and which is further moistened. This air has a heat capacity greater than that of a flow of air of the same temperature taken directly from the passenger compartment, which promotes the transfer of calories to the activated carbon filter and the desorption of polluting molecules.

In this embodiment, the air flows through the filter 3 in the opposite direction during the regeneration phase, with respect to its direction of circulation during the running of the vehicle. This inversion may for example allow to reject outside the vehicle, some of the particles trapped on the surface of the filter, not yet embedded in the filter structure. It should be noted that since the pipes 17 are made of plastic, the maximum temperature at which the air flowing in the device during the regeneration of the filter can be carried is limited by the maximum temperature that the pipes can withstand without being subjected to deformation and loss of sealing. The temperatures that can withstand the pipes being often less than 90 ° C, one can for example provide a regeneration procedure in which is circulated through the filter 3, regeneration air heated to temperatures for example between 50 and 70 ° C for a predetermined time. If, for this preset time and temperature, the air arriving on the filter has a high humidity level, following its passage on the evaporator 4, the regeneration may be more efficient. Figures 3a and 3b show another embodiment of the invention. FIGS. 3a and 3b show elements that are common to FIGS. 1a and 1b, the same elements then being designated by the same references.

Figure 3a shows the device in the normal ventilation mode of the passenger compartment, for example while driving the vehicle. Outside air enters the device through an air inlet (not shown). The blower 5 then directs the fresh air between two bypass flaps 24 and 25 to the filter 3 and then to the evaporator 4. After passing on the evaporator 4, the air flow is then split into two streams passing one under the mixing flap 11 to cross the heater 7 then the resistor 6, and the other above the mixing flap 11 to avoid exchanges with the heater or resistance. The resulting flow is then distributed using the distribution flap 12 in the various pipes 17, bringing it to different places of the passenger compartment. In ventilation mode, the direction of air flow is therefore very similar to that of the embodiment of FIG. As the embodiment of Figure la, the embodiment of Figure 3a is provided with a condensate discharge channel, which is closed by a bypass flap 24 during normal ventilation of the vehicle. FIG. 3b shows the embodiment of the invention of FIG. 3a during its operation in regeneration mode of the filter. In regeneration mode, the blower 5 activates a flow of air from the passenger compartment towards the filter 3. The bypass flaps 24 and 25 and the mixing flap 11 are this time arranged so that the air flow first passes through the distance 6 and the heater 7, then passes on the evaporator 4, and finally passes through the filter 3 before leaving the vehicle via the condensate discharge channel 10, to which the flap by-pass 24 cleared access. Behind the filter 3, that is to say downstream of the filter 3 with respect to the flow of air circulating in the regeneration mode, is disposed a humidity sensor 26. When the electronic control unit has determined that a a sufficient number of conditions were verified to trigger a regeneration cycle, it causes the positioning of the various flaps for the air supply device is found in the configuration of Figure 3b, it activates the blower 5, triggers the heating of the resistor 6 powered by the energy of the battery 2, this energy being immediately compensated by the electrical energy arriving from the external network 20, and records the values of the humidity sensor 26. The humidity sensor 26 can, according to the case, be coupled to a temperature sensor 46 disposed downstream of the filter, or disposed more generally downstream of the resistor 6 in airflow mode corresponding to the regeneration of the filter. The electronic control unit may make the timing of the stop of the regeneration cycle dependent on the hygrometry level and / or on the temperature measured by the temperature and humidity sensors 26. It will be noted that in this mode of realization, the air from the cabin is first heated by the resistance 6, benefits from a possible extra calories from the heater 7, then is sent on the evaporator 4 which is traversed by an air preheated, allowing it to dry out in a shorter time. The air arriving on the filter 3 is already both hot and loaded with moisture, which makes it possible to obtain a particularly efficient regeneration. The condensate discharge channel 10 of FIGS. 1a, 1b, 3a and 3b may correspond to a discharge channel initially designed for the sole flow of the condensates from the air conditioning associated with the evaporator 4. This evacuation channel may also be enlarged, or its section can be increased by practicing several neighboring orifices. It is of course possible to provide an air supply device in which it is possible, during the regeneration phase, to simultaneously heat the filter and a resistance in the path of the air coming from the passenger compartment. In all the embodiments described, the heating time of the filter and / or the resistance, as well as the objective temperature that is to be obtained at the inlet of the filter, are limited by the temperature resistance of the filter, evaporator and ducts guiding the flow of air considered. On the other hand, the heating intensity is in no way limited by the energy available at the battery, since this energy is immediately compensated by the power supply from the external network intended to recharge the battery. The regeneration step can be prolonged to the length of time deemed necessary to obtain effective regeneration of the filter or, if this second period is longer, to the time necessary to effectively dry the evaporator. This latter strategy subsequently limits the proliferation of bacteria on the evaporator and the foul smells in the cabin. It is possible, thanks to the invention, to develop regeneration strategies whose main priority is no longer to limit the total energy necessary for regeneration, but whose priority becomes the efficiency of the regeneration cycle, and the limitation of nuisance to the occupants of the vehicle. It is thus possible, for example, to decide to trigger the regeneration operation only after the occupants have a priori moved away from the vehicle, allowing a certain period of time between the connection of the battery for reloading. , and the regeneration operation. This waiting time may involve a slight cooling of the hot cooling liquid present in the heater, which is easily compensated by the heating of the filter or the resistor 6. This period of time also allows the evaporator 4, if the air conditioning was in operation just before stopping the vehicle, lose some of the moisture that has condensed on it, and slightly increase in temperature, which facilitates its subsequent drying. FIG. 4 illustrates an exemplary control algorithm of the device according to the invention as described in FIGS. 1a, 1b, 2a, 2b, 3a, 3b, by its electronic control unit. In particular, this algorithm illustrates how the start and end times of regeneration phase of the filter 3 can be determined. When the electronic control unit detects that the vehicle is stopped in a step 27, it performs a test 28 to find out if the vehicle doors are locked, and the battery has been plugged in for charging. If these two conditions are verified, the electronic control unit, in a step 29, will search in a memory for a KMReg value indicating the mileage of the vehicle corresponding to the last regeneration of the filter, and check if the KM running kilometer of the vehicle is greater than the incremented memory value by a predefined 4KM value. If this mileage condition is verified, the electronic control unit proceeds to a test step 31 to verify whether the vehicle is being connected to a confined garage, or whether the vehicle is parked in an outdoor charging zone. If the mileage condition of step 29 is not verified, the electronic control unit performs a test in which it compares a Time_Clim counter, which counts the time of operation of the air conditioning of the device since the last regeneration, is greater than a Do threshold. If this second condition of use time of the air conditioning is verified, the electronic control unit also goes to step 31 to check whether the vehicle is being reloaded on a terminal placed outside.

In step 31, the electronic control unit seeks to determine whether the vehicle is parked outside, for example if the temperature Text determined by an outside temperature sensor is lower than a first threshold value T1 or is instead higher than a second threshold value T2, or if the brightness Lux of a brightness sensor is greater than a threshold value Lux ° - If the response is negative, the electronic control unit does not trigger the regeneration phase in order to avoid to reject pollutants in a confined environment. If the response is positive, the electronic control unit initializes a time counter t to zero in step 32, and re-performs the test 28 to find out if the vehicle is being charged with its locked doors. The electronic control unit then increments the time counter t and the calculation step 33 until at a test step 34, the time counter becomes greater than a finite value. When the time counter has become greater than finite, it may be considered, depending on how it has been defined, either that the occupants of the vehicle have sufficiently moved away from the vehicle, or that the temperature of the evaporator has sufficiently approximated the ambient temperature to facilitate the drying of the evaporator, that is, that the condensation on the evaporator has sufficiently drained by gravity to promote the dewatering step of the evaporator. The iteration on the time counter "t" between the reset of the time counter in step 32, and the end of the incrementation of the counter following a positive result of the test 34, represents a verification procedure 41. of a particular state of the vehicle, in which the battery is charging, the occupants have a priori removed, and, depending on the choice of the value of Tini, the evaporator is in a state facilitating its drying Once, at step 34, the electronic unit has determined that sufficient time has elapsed since the connection of the battery on an external network, the electronic control unit starts, in a step 35, the operation in regeneration mode of the device: it positions the flaps of the device adequately, for example according to Figures lb, 2b, 3b, actuates the blower 5, activates the heating means which may comprise resistive means integrated in the filter, the resistor 6, or a p electric pump for circulating the still hot liquid of the cooling circuit in the heater 7. Concomitantly in step 35, the control unit resets the counter t or another time counter at a step 36 , and recheck by test 28 if the battery is still being recharged and the vehicle doors are still locked. If at this stage the electronic control unit detects that the doors have been opened, or the battery has been disconnected, it interrupts the regeneration process and returns the air supply device to the normal air ventilation configuration. cockpit, for example according to Figures la, 2a, 3a. If, on the other hand, the result of the test 28 is positive, the electronic control unit regularly carries out a test 37 to find out if the air temperature Tai, measured by the sensor 26 or by another temperature sensor placed on the circuit of regeneration air, is greater than an optimal regeneration temperature Tai, reg. If this normal temperature is reached, the electronic control unit increments the time counter t, and continues the connections state and optimum temperature checks until the time counter reaches a value tfin at step 39.

When the objective duration tfin regeneration is reached, the electronic control unit checks in a step 40 if the degree of hygrometry Hr measured by the sensor 26, has fallen below a threshold value Hro. According to the variant embodiments, instead of monitoring in terms of the threshold value as indicated in step 40, the electronic control unit could also monitor a level of stability of the degree of humidity Hr, for example by carrying out a test to determine if the degree of hygrometry has changed by less than 4Hr since the last reading of the measured Hr value.

Once the duration conditions tested at step 39 and hygrometry tested in step 40 are both satisfied, the single electronic control stops the regeneration step, that is to say that it cuts off the power of the blower and electric heating means. It also places the various by-pass, distribution, mixing ... flaps in their configuration corresponding to the normal ventilation mode of the passenger compartment of the vehicle. The electronic control unit also resets the Time_Clim counter which will be incremented during the next uses of the air conditioning of the vehicle, and sets the KMReg counter to the KM value corresponding to the current mileage of the vehicle. The object of the invention is not limited to the embodiment described, and can be declined in many variants. One can for example consider taking the air used for the regeneration of the vehicle, directly outside the vehicle, if for example the outside temperature is higher than the temperature in the passenger compartment. It is possible to modify the conditions for triggering and stopping the regeneration cycle, this cycle only being triggered during a recharging step of the battery from an external electricity source. The resistors for heating the air passing through the filter may be resistors which are also used for regulating the temperature of the passenger compartment, or dedicated resistors serving only during the regeneration phase. The filter 3 may be a combined filter comprising both active carbon layers and filter layers, and that one changes beyond a certain mileage of the vehicle. The filter 3 may also be a filter containing only the active substances intended for filtering the polluting gaseous species associated with a removable particulate filter independently of the filter 3. It is then possible, thanks to the efficient regeneration of the filter 3, to lengthen the mileage. recommended between two replacements of the particulate filter. It can be provided to operate the blower at comparable speed during the regeneration phase and during normal ventilation of the passenger compartment. It is also possible to activate the blower at a higher speed during the regeneration phases, the occupants of the vehicle not being present to suffer the resulting noise nuisance. It may also be decided to operate the blower only at moderate speed during the regeneration phase, to facilitate the heating of the air in contact with the resistors or the filter. The air supply device according to the invention makes it possible to replace the filter carrying the active substances less often, and considerably improves the olfactory comfort of the occupants of the vehicle. On the one hand it maintains a high ability of the filter to capture the polluting species, and on the other hand 1 allows to regularly dry the air conditioner of the vehicle to avoid the proliferation of bacteria, molds or other living species generating odors undesirable.

The device according to the invention does not affect the reserve of energy available in the battery, which helps to optimize the autonomy of the vehicle. In addition, the device is triggered when the occupants have a priori away from the vehicle for an extended period of time: the regeneration step therefore does not affect the occupants of the vehicle from the olfactory, thermal or auditory point of view. The invention applies, preferably, to motor vehicles with electric propulsion, or hybrid propulsion that is to say partially electric and partially provided by another energy source. The invention could however also apply to a vehicle powered by an alternative energy source (hydrogen) and which would be provided with a battery supplying other functions of the vehicle, the battery being designed to be reloaded periodically on an outside source while the vehicle is stationary.

Claims (11)

REVENDICATIONS1. Device (1) for the supply of cabin air to a motor vehicle with electric or hybrid propulsion, equipped with a power supply battery (2), the device comprising a gas filter (3) and a resistor ( 6) heating able to heat the filter (3) or to heat air arriving at the filter (3) during a regeneration phase of the filter (3), characterized in that the device (1) comprises a unit electronic control unit configured to activate the heating resistor during a vehicle stopping step where the battery (2) is in the electric charging stage from an external network (20) to the vehicle. 2. Device according to claim 1, comprising a status counter for evaluating an elapsed time (ClCl_length) and / or a mileage traveled since the last regeneration phase, and a validating unit allowing a new regeneration phase if the time or mileage is greater than a predefined threshold (Do, OKM), and if a recharge phase of the battery (2) on the external network (20) has been activated during a validation threshold time (finite). 3. Device according to one of the preceding claims, wherein the resistor comprises a resistor (6) also for heating air arriving in the passenger compartment in a first mode of operation distinct from the regeneration phase. 4. Device according to one of the preceding claims, comprising an electric pump for circulating liquid of a cooling circuit through a heater (7) during the regeneration phase. 5. Device according to one of the preceding claims, comprising an air conditioner whose evaporator (4) is interposed in the path of the air flowing during the regeneration phase between the passenger compartment and the outside of the vehicle. 6. Device according to claim 5, wherein the evaporator (4) is, during regeneration, downstream of the resistor (6) in the path of a flow of air for regeneration. 7. Device according to the preceding claim, comprising a filter (3) activated carbon with integrated resistive son, which during the regeneration phase is upstream on a regeneration air flow relative to the evaporator (4). . 8. Device according to one of claims 5 or 6, wherein the evaporator (4) is, during regeneration, upstream of the filter (3) to regenerate. 9. Device according to one of claims 5 to 8, wherein the control unit is connected to a humidity sensor (26), and is configured to compare the measurement of the sensor (26) with respect to a threshold of humidity (HR0) in order to decide whether or not to close the regeneration phase. 10. A method of regenerating a filter (3) for a passenger compartment of a motor vehicle, in which a specific flow of air is activated from the passenger compartment towards the outside of the vehicle, through the filter (3), as well as resistive heating means (6, 3), during a recharging phase of a battery (2) of the vehicle from an electrical network (20) outside the vehicle. 11. Regeneration process of a filter (3) according to claim 10, wherein activates a specific flow of air from the passenger compartment to the outside of the vehicle, through the filter (3), as well as resistive heating means (6, 3), during a recharging phase of a battery (2) of the vehicle from an electrical network (20) outside the vehicle, after having carried out a verification procedure (41) allowing consider that all the occupants of the vehicle have left it.