FR2971944A1 - Air treatment device for treating air in passenger compartment of car, has diffuser for diffusing volatile product e.g. perfume, in main duct so as to be driven to output by air flow generated by blower - Google Patents

Abstract

The device (D) has an atomizer (MN) for producing very small droplets from liquid, and a blower (MP) for generating flow of air. A main duct (CP) channels a part of the generated air flow and resultant droplets to an outlet (SD) connected with a chamber. A diffuser diffuses a volatile product e.g. perfume, in the main duct so as to be driven to the output by the generated air flow, and a control unit (MCD) is arranged to authorize or prohibit the production of the droplets by the atomizer according to received instruction. An independent claim is also included for a method for treating air in an enclosure.

Description

The invention relates to the treatment of air which is intended for certain enclosures. The invention relates to the treatment of air for a loudspeaker, by diffusion of a volatile product in an air flow mixed with nebulized liquid drops. By "air treatment" is meant here the addition of one or more external elements (or components) to air prior to dispensing it into an enclosure. Furthermore, the invention relates to any type of enclosure, including vehicle interiors, possibly automotive type, and rooms or building rooms. As known to those skilled in the art, certain air treatment devices 15 are intended to cool enclosures by increasing their hygrometry by means of drops of liquid resulting from nebulization. To do this, some of these devices comprise, firstly, nebulizing means for producing very small drops (in the form of a mist) from a liquid, a second part, production means responsible for generating an air flow (possibly coming from the enclosure), and, thirdly, a main duct capable of channeling the generated air flow and the nebulized drops produced to a output that communicates with the speaker. Unlike an air conditioner which generates a cooled and dry air (reduced hygrometry) which may be inconvenient for some people (and in particular for those who wear contact lenses), an air treatment device of the aforementioned type cooled the air it receives by humidifying it by means of the nebulized drops which are partially evaporated by the flow of air. Furthermore, when an air treatment device of the aforementioned type is supplied in a closed circuit with the air of the enclosure that it supplies, it provides enclosure cooling which is much more progressive than that provided by a conventional air conditioner, which significantly improves aerothermal comfort. In addition, an air treatment device of the aforementioned type can be advantageously combined with an air conditioner, because it contributes to humidify the dry air supplied by the latter by consuming little energy. The invention aims to provide an air treatment device capable of offering several air treatments, which can be optionally combined with each other. It proposes in particular for this purpose a device, dedicated to the treatment of an air which is intended for an enclosure, and comprising: - nebulization means suitable for producing very small drops from a liquid, - means of production capable of generating an air flow, a main duct capable of channeling at least a portion of the air flow generated and the drops produced to an outlet which communicates with the enclosure, and diffusion means suitable for diffusing a volatile product in the main duct so that it is driven to the outlet by the air flow generated. Thanks to such a treatment device, it is therefore possible to cool an enclosure by humidification and / or to diffuse a volatile product (such as, for example, a perfume, a purifying product, a disinfectant product, or a decontaminating product). It will be noted that the diffusion of a volatile product in a slightly humid atmosphere may favor the effect induced by this volatile product in a chamber (by way of non-limiting example, if the fragrance is a menthol extract, it may be feeling of increased subjective freshness).

The air treatment device according to the invention may comprise other characteristics which may be taken separately or in combination, and in particular: its diffusion means may be suitable for supplying its main duct with volatile product diffused downstream or else upstream of the nebulization means; its diffusion means may comprise generation means capable of diffusing the volatile product, and an auxiliary conduit comprising, firstly, an intermediate part capable of receiving at least a part of the generation means for collecting the volatile product diffused. , a second part, a first end connected to the main pipe upstream. This implementation optimizes efficiency, particularly in terms of consumption of volatile product (for example it does not saturate the nose perfume by controlling the diffusion of the latter by means of a time delay and via motorized valves); fogging means for taking at least a portion of the ducted air stream and driving the diffused and collected volatile product and, thirdly, a second end capable of supplying the main duct with diffused volatile product , collected and trained; it may comprise access control means adapted to allow or prohibit the access of the air flow generated in the auxiliary duct as a function of a first command received, and control means capable of generating the first control in function of a received instruction; - The control means may be arranged to generate a second command, intended to allow or prohibit the production of drops by the nebulizing means, according to a received instruction; the control means can be arranged to generate a third command, intended to allow or prohibit the generation of the air flow by the production means, according to a received instruction; its production means may be able to generate the flow of air from an air taken from the enclosure; - its means of production may include an air blower; its nebulizing means may comprise a nebulization chamber connected to the main duct by a connecting duct; its nebulizing means may comprise a reservoir storing liquid and connected to the nebulization chamber, and detection means able to estimate the level of liquid present in the nebulization chamber so as to order a transfer of liquid from the reservoir to the nebulizing chamber when the estimated liquid level is below a first chosen threshold; the detection means may be suitable for preventing the production of the drops by the nebulization means when the estimated liquid level is lower than a second chosen threshold, itself lower than the first threshold chosen; the reservoir may comprise at least one pre-filled cartridge in liquid; it may furthermore comprise collection means, connected to the main duct in the vicinity of the outlet, and arranged to collect condensates of liquid; - The collection means may be arranged to supply the collected condensate tank.

The invention also proposes a central console, intended to equip a vehicle between two of its seats, and comprising an air treatment device of the type shown above. The invention also provides a vehicle comprises an air treatment device of the type shown above, or a central console of the type shown above. The invention also proposes a method, dedicated to the treatment of an air that is intended for an enclosure, and comprising the following steps: i) supplying a main duct with a stream of air, ii) producing by nebulization, from a liquid, very small drops, and inject these drops in the main conduit, iii) diffuse a volatile product in the main conduit, and iv) route through the main conduit to an outlet that communicates with the enclosure , the airflow, the drops produced and the volatile product diffused.

Other characteristics and advantages of the invention will emerge on examining the detailed description below, and the attached drawing, in which the single figure schematically and functionally illustrates a central vehicle console equipped with an exemplary embodiment. of a treatment device according to the invention. The attached drawing may not only serve to complete the invention, but also contribute to its definition, if any.

The invention aims to provide an air treatment device (D) for supplying treated air in a chamber. In what follows, it is considered, by way of non-limiting example, that the enclosure is a passenger compartment of a motor vehicle, such as a car. But, the invention is not limited to this type of enclosure. It concerns indeed any type of enclosure, including vehicle interiors, whatever the type, and rooms or rooms of buildings or even verandas. Furthermore, it is considered in the following, by way of non-limiting example, that the air treatment device (D) is located in a central console (CC) installed between two seats of a vehicle. But, the invention is not limited to this type of implantation. Thus, an air treatment device (D) can also be located in an engine compartment or a dashboard or a vehicle trunk, or in a wall or false ceiling of a building, for example. FIG. 1 shows diagrammatically a central vehicle DC console comprising an internal housing in which a processing device D according to the invention is installed. As illustrated, a (treatment) device D comprises nebulization means (or nebulizer) MN, production means MP, a main line CP, and diffusion means MD.

The production means MP are arranged to generate an air flow. To do this, they (MP) may for example comprise an air blower electrically powered by the vehicle electrical network, and comprising an inlet adapted to take air at an EA air intake (F1 arrow). ), here belonging to the central console CC, and an output connected to the input of the main pipe CP to supply air flow (arrow F2). Preferably, the pulser MP is variable speed to produce different flow rates of air flow as needed.

It will be noted that the air intake EA may, for example, open into the passenger compartment of the vehicle. It will be understood that in this case the production means MP generate the flow of air from an air that is taken from the passenger compartment (or enclosure) (arrow F1). But, this is not mandatory. Indeed, the input of the blower could be connected to a conduit or an outlet of an air conditioning installation (here of the vehicle), in order to be powered by this installation. In the case of a vehicle passenger compartment, it is preferable that the EA air intake is oriented towards the front part of the passenger compartment, where the tier 1 seats are installed (for the driver and the passenger (s) before), to take air to treat. The nebulizing means (or nebulizer) MN are arranged to produce very small drops in suspension (in the form of a "mist" or a "mist") from a liquid. Typically, the drops have a diameter of between about 2 μm and about 5 μm. The liquid to be nebulized is for example water. Note that this water may be optionally demineralized, or added chemical product (s), such as a disinfectant. Any nebulization technique known to those skilled in the art can be used here. By way of example, and as illustrated in no way in the single figure, the nebulizer MN may comprise a CN nebulizing chamber containing a liquid to be sprayed (here water) and a piezoelectric oscillator OP which vibrates to very high frequency when it is supplied with voltage (here by the electrical network of the vehicle). For example, in the case of an ultrasonic nebulizer, the vibrating surface is actuated by ultrasound (i.e., at a frequency greater than 20000 Hz). This piezoelectric oscillator OP is immersed in the water to be sprayed in order to generate on the surface of this water a mist or a mist composed of droplets of microscopic dimensions.

As illustrated, the fogging chamber CN may have a coupled inlet, via a transfer conduit CT, to a tank RL which is intended to supply water to be sprayed (arrow F10). Note that in order to avoid damage to the piezoelectric oscillator OP, it is preferable to maintain in the nebulization chamber CN a liquid level higher than a first chosen threshold. For this purpose, the fogging chamber CN may comprise detection means (not shown) capable of estimating the level of the liquid that it contains. In this case, the detection means are arranged to order a transfer of liquid from the tank RL to the nebulization chamber CN (arrow F10) when the estimated liquid level is lower than the first threshold chosen. In order to take account of variations in the height of the liquid level in the CN fogging chamber, generated by the displacement of the vehicle and for example because of a bend or a slope that has been going up or down, the detection means can, for example, for example, be coupled to at least one sensor for measuring the weight of the nebulization chamber CN which is representative of the volume of liquid contained and therefore the level of liquid.

Furthermore, the detection means may also be arranged to prevent the nebulizer MN (and more precisely here its piezoelectric oscillator OP) from producing nebulized drops when the estimated liquid level is lower than a second chosen threshold which is even lower than the first threshold chosen.

It will also be noted that the reservoir RL can constitute or comprise at least one pre-filled cartridge in liquid, which is replaced once it is empty. But, in one variant, the tank RL could comprise an inlet provided with a stopper and intended to allow its filling by a user.

The nebulized drops are intended to feed the main pipe CP at an intermediate portion (arrow F4). To do this, the NC fogging chamber can be connected to the main pipe CP via a connecting pipe CL, as illustrated. Note that to facilitate this supply of nebulized drops, the nebulizer MN may be associated with a fan (not shown). The latter creates an auxiliary air flow that drives the nebulized drops to the main duct (arrow F4). In one variant, a bypass duct may be provided between the main duct CP and the nebulizer MN, in order to take upstream of the latter (MN) a small portion of the air flow generated by the blower MP and circulating in the duct. main pipe CP, so that it feeds the fogging chamber CN and thus drives the nebulized drops to the main pipe CP (arrow F4).

The main pipe CP is able to channel at least a portion of the air flow that is generated by the pulsator MP and the nebulized drops that are produced by the nebulizer MN to an output SD, which communicates with the passenger compartment (or pregnant). In the case of a vehicle interior, it is preferable that the SD exit (here from the center console CC) is oriented towards the central or rear part of the passenger compartment, where the seats of rank 2 are installed in order to distribute the air treated by the device D (arrow F8). The diffusion means MD are arranged to diffuse a volatile product in the main conduit CP so that it is driven to the output SD by the air flow generated by the pulsator MP. In the nonlimiting example illustrated in the single figure, the diffusion means MD feed the main pipe CP volatile product diffused downstream of the nebulization means MN. But, in a variant, they (MD) could supply the main pipe CP volatile product diffused upstream of the nebulization means MN. This latter variant can induce a reduction in the time of use of the MD cartridge containing the volatile product and / or a saturation effect of the nose in the case of a perfume. Moreover, in the nonlimiting example illustrated in the single figure, the diffusion means MD comprise generating means MG and an auxiliary duct CA. These generation means MG are arranged to diffuse the volatile product in the presence of an air flow. For example, they (MG) may be in the form of a body or a cartridge comprising a recessed portion in which is housed a volatile product to be diffused. For this purpose, the wall of the body (or cartridge) which defines the recessed portion may comprise at least one window (or openings) intended to allow the flow of air to lick the volatile product. Any compact means for diffusing a volatile product and known to those skilled in the art can be used here. The volatile product can be of different types as needed. Thus, it may be a perfume (or fragrances), or a product intended to purify the air (for example an alcoholic solution), or a disinfectant product, or a decontaminating product ( for example to prevent the spread of a contagious disease), or even essential oils (wick impregnated with volatile perfume or impregnated ceramic heated by an electrical resistance). The body or the cartridge MG may for example be clipped or screwed into the auxiliary duct CA. Moreover, the central console CC may for example comprise an orifice provided with a cap or cover and intended to allow the removal or insertion of the body or the MG cartridge. Note that in an alternative embodiment that is not currently preferred because of its less modularity and its lower efficiency, the body (or cartridge) MG may be partially housed in the main conduit CP. In this case, the MD diffusion means do not include a CA auxiliary conduit. In the nonlimiting example illustrated in the single figure, the auxiliary duct CA has an intermediate portion PI joining first E1 and second E2 ends. The intermediate portion PI is intended to receive at least a portion of the generation means MG in order to collect the diffused volatile product. For this purpose, it may for example comprise an opening in which may be introduced an end of the body (or cartridge) MG which comprises the volatile product to be diffused, for securing it to the auxiliary duct CA. The first end E1 is connected to the main pipe CP upstream of the nebulization means MN, that is to say in an area between its end connected to the pulser MP and its junction zone with the connecting pipe CL. This first end E1 is intended to take at least a portion of the air flow which is channeled in the main pipe CP (arrow F5), so that this part causes the volatile product diffused by the generating means MG and collected by the party intermediate PI of its auxiliary duct CA (arrow F6).

The second end E2 is here connected to the main pipe CP downstream of the nebulization means MN, that is to say in an area between its junction zone with the connecting pipe CL and its end connected to the output SD. But, as mentioned above, it could be envisaged that the second end E2 is also connected to the main pipe CP upstream of the nebulization means MN, that is to say in an area located between its end connected to the pulser MP and its zone. junction with the connecting conduit CL. In one case as in the other, this second end E2 is intended to feed the main pipe CP volatile product diffused, collected and driven. It will be noted, as illustrated not only in the single figure, that it is particularly advantageous that the device D also comprises access control means MCA intended to allow or prohibit access to the air flow generated by the blower MP in the auxiliary duct CA, according to a first command provided by MCD control means also part of the device D. It will be understood that the control means MCD are themselves arranged to generate a first command based an instruction provided by an actuator (not shown), operable by a user, directly or indirectly.

These access control means MCA are particularly useful because they give the device D an important modularity. Indeed, when the access control means MCA allow access of a portion of the air flow in the auxiliary duct CA, the device D can deliver at the output SD a stream of air cooled by humidification by means of nebulized drops, and containing dispersed volatile product. On the other hand, when the MCA access control means prohibit access of a portion of the air flow in the auxiliary duct CA, the device D can deliver at the output SD only a stream of air refreshed by humidification by means of nebulized drops, and thus devoid of diffused volatile product. The user can thus choose which treatment (s) he wants the device D to bring to the sampled air (here in the cabin). As illustrated not only in the single figure, the access control means MCA may comprise a flap (or valve) VA, installed Il in the auxiliary duct CA, and an electric motor MO, coupled to the control means MCD and arranged so as to place the flap (or valve) VA in an open state or a closed state according to the first instruction provided by the MCD control means.

It will also be noted, as illustrated not only in the single figure, that it is particularly advantageous for the control means MCD to be arranged to generate a second command intended to allow or prohibit the production of the drops by the nebulization means MN (and more specifically by the piezoelectric oscillator OP), according to an instruction provided by an actuator (not shown), operable by a user, directly or indirectly. This option is particularly advantageous because it makes it possible to further increase the modularity of the device D. Indeed, when the MCD control means allow the piezoelectric oscillator OP to produce nebulized drops, the device D can deliver at the level of the output SD a stream of air cooled by humidification by means of nebulized drops, and optionally containing diffused volatile product. On the other hand, when the MCD control means prohibit the piezoelectric oscillator OP from producing nebulized drops, the device D can deliver at the output SD only a stream of air that has not been refreshed, but possibly mixed with volatile product released. This therefore offers the user an even greater choice of air treatments. It will also be noted, as illustrated not only in the single figure, that it is advantageous for the control means MCD to be arranged to generate a third command intended to authorize or prohibit the generation of the air flow by the production means MP. according to an instruction provided by an actuator (not shown), operable by a user, directly or indirectly. Even more preferably, the third command generated by the MCD control means can be used to set the flow rate of the air flow that is generated by the pulser MP, according to the needs of the user. It will also be noted, as illustrated not only in the single figure, that the device D may comprise collection means MCN connected to its main conduit CP in the vicinity of the output SD and arranged to collect condensates of liquid so that it not broadcast in the passenger compartment. These condensates result from the condensation of a part of the nebulized drops, in particular because of their contact with the inner wall of the main pipe CP. The collection means MCN may, for example, comprise a GC grid whose holes have dimensions greater than those of nebulized drops (for example, and not limited to, 10 microns or 20 microns) in order to let them pass and to retain only the condensates.

The evacuation of these condensates out of the main pipe CP can be done by means of a discharge pipe CO, which communicates with the main pipe CP possibly via a condensate tray (not shown). In the nonlimiting example illustrated in the single figure, the discharge pipe CO feeds the tank RL collected condensates so that they can be reused by the nebulizer MN. But, these condensates collected could possibly be evacuated outside the passenger compartment, through the floor of the vehicle. It is important to note that the invention can also be considered from the angle of an air treatment method, which can be implemented in particular by means of an air treatment device D of the type presented. above. Since the functionalities offered by the implementation of the method according to the invention are identical to those offered by the air treatment device D presented above, only the combination of main functionalities offered by the method is presented hereinafter.

This air treatment method comprises the following steps: i) feeding a main pipe CP with a flow of air, ii) producing by nebulization, from a liquid, very small drops, and injecting these drops into the main pipe CP, iii) diffusing a volatile product in the main pipe CP, and iv) conveying by means of the main pipe CP, to an output SD which communicates with the enclosure, the air flow, the drops produced and the volatile product diffused.

The invention is not limited to the above-described embodiments of air handling apparatus, center console, vehicle and air treatment method, by way of example only, but encompasses all variants that may be considered by those skilled in the art within the scope of the claims below.

Claims (19)

REVENDICATIONS1. An air treatment device (D) for an enclosure, comprising i) nebulization means (MN) capable of producing very small drops from a liquid, ii) production means (MP) capable of generating a air flow, and iii) a main duct (CP) capable of channeling at least a portion of said generated air flow and said produced drops to an outlet (SD) communicating with said enclosure, characterized in that further comprises diffusion means (MD) for diffusing a volatile product in said main conduit (CP) so that it is driven to said output (SD) by said generated air flow. 2. Device according to claim 1, characterized in that said diffusion means (MD) are adapted to supply said main conduit (CP) volatile product diffused downstream of said nebulizing means (MN). 3. Device according to claim 1, characterized in that said diffusion means (MD) are adapted to supply said main pipe (CP) volatile product diffused upstream of said nebulizing means (MN). 4. Device according to one of claims 1 to 3, characterized in that said diffusion means (MD) comprises generating means (MG) adapted to diffuse said volatile product, and an auxiliary duct (CA) having an intermediate portion (PI) adapted to receive at least a portion of said generating means (MG) for collecting said diffused volatile product, a first end (E1) connected to said main pipe (CP) upstream of said nebulizing means (MN) in order to collect a at least part of said ducted air stream and to drive said dispersed and collected volatile product, and a second end (E2) adapted to supply said main duct (CP) with diffused, collected and driven volatile product. 5. Device according to claim 4, characterized in that it comprises access control means (MCA) adapted to allow or prohibit access to said air flow generated in said auxiliary duct (CA) as a function of a first received command, and control means (MCD) adapted to generate said first command according to a received instruction. 6. Device according to claim 5, characterized in that said control means (MCD) are arranged to generate a second command, intended to allow or prohibit the production of said drops by said nebulizing means (MN), according to a instruction received. 7. Device according to one of claims 5 and 6, characterized in that said control means (MCD) are arranged to generate a third command, intended to allow or prohibit the generation of said air flow by said means of production (MP) , depending on a received instruction. 8. Device according to one of claims 1 to 7, characterized in that said production means (MP) are adapted to generate said air flow from an air taken from said enclosure. 9. Device according to one of claims 1 to 8, characterized in that said production means (MP) comprise an air blower. 10. Device according to one of claims 1 to 9, characterized in that said nebulizing means (MN) comprises a nebulization chamber (CN) connected to said main conduit (CP) by a connecting conduit (CL). 11. Device according to claim 10, characterized in that said nebulizing means (MN) comprises a reservoir (RL) storing liquid and connected to said nebulizing chamber (CN), and detection means for estimating the level of liquid present in said nebulizing chamber (CN) so as to order a transfer of liquid from said reservoir (RL) to said nebulizing chamber (CN) when the estimated liquid level is lower than a first chosen threshold. 12. Device according to claim 11, characterized in that said detection means are adapted to prohibit the production of said drops by said nebulizing means (MN) when the estimated liquid level is less than a second threshold chosen, itself lower than said first threshold chosen. 13. Device according to one of claims 11 and 12, characterized in that said tank (RL) comprises at least one cartridge pre-filled with liquid. 14. Device according to one of claims 1 to 13, characterized in that it further comprises collection means (MCN), connected to said main conduit (CP) in the vicinity of said output (SD), and arranged to collect condensates of liquid. 15. Device according to claim 14 in combination with one of claims 11 to 13, characterized in that said collection means (MCN) are arranged to supply said reservoir (RL) collected condensate. 16. Central console (CC) vehicle, suitable to be installed between two seats, characterized in that it comprises an air treatment device (D) according to one of the preceding claims. 17. Vehicle, characterized in that it comprises an air treatment device (D) according to one of claims 1 to 15. Vehicle, characterized in that it comprises a central console (CC) according to claim 16. 19. A method of treating an air intended for an enclosure, characterized in that it comprises the following steps: i) supplying a main duct (CP) with a stream of air, ii) producing by nebulization, from a liquid, very small drops, and injecting these drops into said main pipe (CP), iii) diffusing a volatile product in said main pipe (CP), and iv) conveying by means of said main pipe (CP), until an outlet (SD) communicating with said enclosure, said air flow, said drops produced and said diffused volatile product.