WO2016202584A1 - Air cooling device for a motor vehicle and associated atomizing head - Google Patents

Abstract

The invention relates to an air cooling device (1) for a motor vehicle, comprising: a ventilation member (2) designed to supply a flow of air to the passenger compartment of the vehicle, and an atomizing head (3) for delivering droplets of atomized liquid into the air flow intended for the vehicle passenger compartment and comprising a piezoelectric ceramic (5) which can generate a vibratory movement. According to the invention, the atomizing head (3) also comprises a stationary slotted grille (7) through which the droplets of atomized liquid, generated by the vibratory movement of the piezoelectric ceramic (5), are delivered. The invention also relates to an atomizing head (3) for such an air cooling device (1).

Description

 AIR-REFRIGERATING DEVICE FOR MOTOR VEHICLE AND ASSOCIATED NEBULIZATION HEAD

The invention relates to an air cooling device for a motor vehicle. The invention also relates to a nebulizing head for such an air cooling device.

 To ensure the thermal comfort of passengers, motor vehicles most often incorporate a ventilation system and / or air conditioning to establish in the cabin temperature below the external temperature.

 These ventilation and / or air conditioning systems ventilate cooled air so that they bring thermal comfort to the occupants of the vehicle.

 A first disadvantage of such systems is that the cooled air is dried. In addition, the seats at the rear of the cabin are often less well ventilated, so they are also less refreshed.

 It should also be noted that not all vehicles are equipped with an air conditioner.

 In order to improve the situation, it is known to nebulise a liquid such as water. For this purpose, a known solution is to provide an air cooling device including in particular an aeration member through which circulates a flow of air, and a nebulizing head, which can in particular be arranged at the level of the aeration member, so as to deliver microdroplets or droplets of nebulized water into the airflow for ventilation and / or ventilation. The droplets evaporate causing a lowering of temperature due to the latent heat of vaporization which is then absorbed. This is transparent for the passenger or passengers of the vehicle, for example, who feels only the sensation of freshness without perceiving an increase in humidity.

Such a solution makes it possible at least partially to overcome the absence of an air conditioner or to improve the cooling of the passenger compartment when such an air conditioner is present, but insufficient locally. This solution also helps to humidify the air. According to the known solutions, the nebulizing head comprises a piezoelectric transducer having a substantially cylindrical body, a piezoelectric ceramic of substantially annular shape arranged to vibrate the piezoelectric transducer, and a perforated membrane arranged at one end of the piezoelectric transducer so as to be vibrated by the piezoelectric transducer.

 Conventionally, the micro-perforated membrane has a very small thickness, for example of the order of 40μιη, and can therefore be easily deteriorated.

 In addition, the piezoelectric ceramic and the perforated membrane are separated by the body of the intermediate piezoelectric transducer which amplifies the vibrations to the membrane. This intermediate piezoelectric transducer has the disadvantage of increasing the size of the nebulizing head. In addition, with this known solution, the body of the piezoelectric transducer adds a thickness, which decreases the passage section of the air flow when the nebulizing head is mounted on an aeration member through circulates a flow of air. 'air.

 In addition, to facilitate integration on a particular aeration member, it is known to assemble the nebulizing head in a housing to be received in turn in a housing complementary to the aeration member. This further increases the overall size of the air freshening device receiving the nebulizing head in its housing.

 The invention therefore aims to at least partially overcome these problems of the prior art by providing an air cooling device with a smaller footprint while reducing the risk of deterioration of the nebulizing head.

To this end, the subject of the invention is an air cooling device for a motor vehicle, comprising:

 an airing member configured to diffuse a flow of air towards the passenger compartment of said vehicle, and

a nebulizing head configured to deliver droplets of nebulized liquid into the air flow intended for the passenger compartment of said vehicle, and comprising a piezoelectric ceramic capable of generating a vibratory movement, characterized in that the nebulizing head further comprises a perforated grid arranged fixed and through which the droplets of nebulized liquid, generated by the vibratory movement of the piezoelectric ceramic, are able to be delivered.

 The fixed perforated grid is more robust than the vibrating membrane of the solutions of the prior art.

 In addition, it is no longer necessary to provide a piezoelectric transducer which was used to amplify the vibration between the piezoelectric ceramic and a vibrating membrane. As a result, the nebulizing head according to the invention is of compact size compared to the known solutions of the prior art. This can facilitate in particular its integration into the aeration member without increasing the size. Indeed, only the membrane and the piezoelectric ceramic are to be inserted in a housing of the aeration member for example. The case can be removed from the spray head.

The perforated grid is advantageously made of a rigid material so as not to vibrate.

According to one aspect of the invention, the perforations of the perforated grid have a diameter of the order of 5μιη to 15μιη, preferably of the order of 8μιη to 12μιη. We also talk about micro-perforated grid.

According to a preferred embodiment, the piezoelectric ceramic is separated from the perforated grid and is arranged opposite the perforated grid.

 The piezoelectric ceramic and the perforated grid are for example concentric.

According to another aspect, the piezoelectric ceramic is made in the form of a disc with a diameter of the order of 10 mm.

 According to yet another aspect of the invention, the perforated grid of the nebulizing head is made in the form of a disc with a diameter of the order of 10 mm.

This gives a nebulization head very compact compared to the solutions of the prior art, where the ceramic has for example an outer diameter of about 20mm. Advantageously, the perforated grid has a thickness of the order of 1 mm. The risk of damaging the perforated grid of the nebulizing head, for example by touching it, is minimized compared to the solutions of the prior art with vibrating membranes of very small thickness.

According to yet another aspect of the invention, the nebulizing head is mounted on the aeration member, which makes it possible to optimize the mixing between the air flow diffused by the aeration member and the droplets of Nebulized liquid delivered by the nebulizing head.

 With such a nebulizing head, the passage section of the air flow at the level of the aeration member is greater relative to a ventilation member incorporating a head with a piezoelectric transducer intermediate between the piezoelectric ceramic and a vibrating membrane.

 The nebulizing head is for example arranged substantially in the center of the aeration member.

 The aeration member may comprise an at least partially perforated element, for example made in the form of a ventilation grille, in which case the nebulizing head may be mounted on the ventilation grille.

 Advantageously, the perforated grid of the nebulizing head is arranged projecting with respect to the aeration member, on the side of the outlet of the air flow of the aeration member.

 Alternatively, the perforated grid of the nebulizing head is arranged flush with the aeration member, on the side of the outlet of the air flow of the aeration member.

 The droplets of nebulized liquid are therefore delivered downstream of the ventilation mouth of the aeration member from which the air flow is expelled. Thus in automotive application, the droplets are sprayed directly to the passenger compartment of the vehicle, in the air flow.

According to another aspect of the invention, the air cooling device comprises a liquid supply chamber for nebulizing the head of the nebulization, the nebulizing liquid supply chamber being arranged between the piezoelectric ceramic and the perforated grid.

 Preferably, the piezoelectric ceramic is arranged upstream of the nebulizing liquid supply chamber in the direction of flow of the nebulized liquid droplets, and the nebulizing liquid supply chamber is arranged upstream of the perforated grid according to the direction of flow of the nebulized liquid droplets.

 Such a feed chamber dispenses with the use of a porous material, such as a wick, to bring the nebulizing liquid to the fogging head, and thus makes it possible to avoid stagnation of the nebulizing liquid, which would risk promote the proliferation of bacteria and / or bio-films or algae.

In addition, the nebulizing liquid supply chamber may be arranged in the aeration member. The feed chamber can be easily made in the aeration member by a cavity between the piezoelectric ceramic and the perforated grid.

According to another aspect of the invention, the air cooling device comprises a sealing means arranged between the supply chamber and the piezoelectric ceramic.

 The sealing means is for example made in the form of a seal, such as an O-ring.

According to a particular embodiment, the piezoelectric ceramic has a first face and a second face opposite to the first face. The sealing means is arranged on the side of the first face and power supply means of the piezoelectric ceramic are provided on the second face.

 This ensures the seal between the two faces of the piezoelectric ceramic.

The invention also relates to a nebulizing head for an air cooling device as defined above, the nebulizing head comprising a piezoelectric ceramic capable of generating a vibratory movement, characterized in that it further comprises a perforated grid arranged fixed and through which the droplets of nebulized liquid are able to be delivered.

 The fixed perforated grid increases the reliability and the robustness of the nebulisation head, while the vibrations generated by the piezoelectric ceramic make it possible to push the liquid of nebulization through the perforated grid to deliver the droplets of nebulized liquid towards the passenger compartment of the vehicle.

 In addition, the nebulization head no longer has a vibrating membrane and no longer requires a piezoelectric transducer; the nebulizing head accordingly has a compact size which facilitates its integration for example on a ventilation member of a cooling device for a passenger compartment of a motor vehicle.

Other features and advantages of the invention will emerge more clearly on reading the following description, given by way of illustrative and nonlimiting example, and the appended drawings among which:

 FIG. 1 is a diagrammatic front view of an air cooling device according to the invention,

 FIG. 2 schematically represents a profile sectional view of the air cooling device of FIG. 1;

- Figure 3 is a schematic sectional view showing a nebulizing head and a fogging liquid supply chamber of the nebulizing head.

In these figures, the identical elements bear the same references.

 The following achievements are examples. Although the description refers to one or more embodiments, this does not necessarily mean that each reference relates to the same embodiment, or that the features apply only to a single embodiment. Simple features of different embodiments may also be combined to provide other embodiments.

With reference to FIG. 1, the invention relates to a device 1 for refreshing an air flow, for a motor vehicle. The cooling device 1 of an air flow is for example connected to a ventilation network of an existing ventilation and / or air conditioning system in the motor vehicle.

 Alternatively, the cooling device 1 of an air flow may include its own fan, commonly called blower, for moving a flow of air to be treated, to the passenger compartment of a motor vehicle. The power supply of the potential blower can be via an electrical cable connected to the vehicle electrical network or alternatively to an independent energy storage means.

The cooling device 1 of an air flow comprises:

 - A ventilation member 2 for diffusing a flow of air to the passenger compartment of the motor vehicle, and

 - A nebulizing head 3 arranged to deliver droplets of nebulized liquid in the air flow and comprising a piezoelectric ceramic 5 adapted to generate a vibratory movement and a perforated grid 7, or micro-perforated, which is arranged fixed.

 The invention relates more particularly to the nebulization head 3. Aeration device

 According to the particular embodiment of Figures 1 and 2, the aeration member 2, also called aerator, has a crown shape. This aeration member 2 opens into the passenger compartment of a motor vehicle, so as to diffuse a flow of air into the passenger compartment of the vehicle and is "adjustable" so that the user can orient droplets of liquid nebulized at its convenience.

 The aeration member 2 has an opening 9 forming a vent. The opening 9 may have a substantially circular shape, the diameter of which is for example of the order of 60 mm. In addition, the opening 9 of the aeration member 2 defines a housing adapted to receive an at least partially perforated element such as a ventilation grid 11.

The ventilation grid 11 is advantageously mounted movably on the aeration member 2 with at least one degree of freedom, so that the orientation of the grid aeration 11 can be adjusted to change the direction of flow of the air flow.

 The ventilation grille 11 has a periphery 13 of external shape complementary to the shape of the inner wall of the housing of the aeration member 2.

 In addition, the ventilation grille 11 has a plurality of fins 15. According to a particular embodiment illustrated in FIG. 1, the fins 15 extend from the inner face of the periphery 13 of the ventilation grille 11 'to an internal support 17.

 The internal support 17 may be arranged substantially in the center of the ventilation grille 11. The internal support 17 has for example a generally tubular general shape which extends along a longitudinal axis A.

Nebulizer head

 The nebulizing head 3, better visible in Figure 2, is itself configured to dispense droplets of nebulized liquid to the passenger compartment, in the form of mist or fog B.

According to a variant not illustrated, the nebulizing head 3 may be arranged next to the aeration member 2, above, below, or downstream of the aeration member 2 in the direction of flow of the air flow F diffused.

 According to a preferred embodiment illustrated in Figures 1 and 2, the nebulizing head 3 is arranged on the aeration member 2. In this case, the mixture between the air flow F and the mist B generated by the nebulizing head 3 is better.

 In the particular example illustrated, the nebulizing head 3 is mounted in the internal support 17 of the ventilation grille 11. The nebulizing head 3 can be arranged substantially in the center of the ventilation grille 11.

Any fixing means adapted to maintain firstly the piezoelectric ceramic 5 and secondly the perforated grid 7 of the nebulizing head 3 on the aeration member 2 may be mentioned. non-limiting example fastening by clamping, screwing, gluing, or a removable or removable attachment for example by clipping. Preferably, the perforated grid 7 of the nebulizing head 3 is bonded to the aeration member 2. Of course, any other assembly means allowing a reliable connection can be envisaged. In addition, in the case where the nebulizing head 3 is arranged on the aeration member 2, the perforated grid 7 of the nebulizing head 3 can be mounted flush with the ventilation grid 11 and the internal support 17, on the side of the air outlet of the aeration member 2. In other words, the perforated grid surface 7 of the nebulizing head 3 is on the same plane as the surface of its support 17.

 According to an advantageous embodiment, the perforated grid 7 of the nebulizing head 3 is arranged projecting with respect to the ventilation grid 11 and to the internal support 17 of the aeration device 2 on the outlet side of FIG. air of the ventilation unit 2.

 Thus, in operation, the droplets from the nebulizing head 3 are delivered into the air flow F, downstream of the aeration member 2 according to the flow direction of the air flow F, in the case of an automotive application, the droplets from the nebulizing head 3 are therefore delivered directly inside the passenger compartment of the vehicle. Furthermore, according to the invention, the piezoelectric ceramic 5 of the nebulizing head 3 is able to generate a vibratory movement and the perforated grid 7 is fixedly arranged. Advantageously, the perforated grid is made of a rigid material so as not to vibrate.

 The perforated grid 7 is detached from the piezoelectric ceramic 5 and is in particular arranged facing the piezoelectric ceramic 5. With reference to FIG. 3, the piezoelectric ceramic 5 has a first face 5a and a second face 5b opposed to the first face 5a, and the perforated grid 7 is arranged facing the first face 5a of the piezoelectric ceramic 5.

 By way of example, the piezoelectric ceramic 5 and the perforated grid 7 respectively have a general disc shape. In particular, the perforated grid 7 may have a diameter of the order of 10 mm. Similarly, the piezoelectric ceramic 5 may have a diameter of the order of 10 mm. A very compact nebulization head 5 is thus obtained.

 The piezoelectric ceramic 5 and the perforated grid 7 are advantageously concentric.

In addition, in the case where the nebulizing head 3 is arranged on the aeration member 2, the central axis of the perforated grid 7 and the piezoelectric ceramic 5 coincides with the central longitudinal axis A of the inner support 17 of the aeration member 2 (see Figure 2).

 The vibration of the piezoelectric ceramic 5 makes it possible to generate the droplets in the form of mist or fog B. The size of the droplets generated is in particular of the order of 5μιη at 15μιη, preferably of the order of 8μιη at 12μιη. These droplets generated by the vibratory movement of the piezoelectric ceramic 5 are delivered into the cabin via the perforated grid 7 fixed. The perforations of the gate 7 therefore advantageously have a diameter less than 20 μιη, preferably of the order of 5μιη to 15μιη, more preferably of the order of 8μιη to 12μιη. Of course, the size of the perforations of the perforated grid 7 of the nebulizing head is advantageously chosen to obtain droplets with a sufficient flow rate and without the droplets generated being too large not to wet the passengers of the vehicle in particular.

 In order to generate the droplets of nebulized liquid, the nebulizing head 3 is intended to be fed with nebulizing liquid. The nebulizing liquid is for example water.

 Advantageously, any means of supplying nebulizing liquid, promoting the stagnation of the water, which would entail a risk of developing mold or bacteria, are avoided.

According to the embodiment illustrated in FIG. 3, the cooling device 1 comprises a supply chamber 19 for nebulizing liquid of the nebulizing head 3.

 With reference to FIG. 3, the feed chamber 19 is arranged between the piezoelectric ceramic 5 and the fixed perforated grid 7. Thus, the piezoelectric ceramic 5 is arranged upstream of the feed chamber 19 in the direction of flow of the nebulized liquid droplets, itself arranged upstream of the perforated grid 7 according to the direction of flow of the liquid droplets. nebulized.

More specifically, in this example, the feed chamber 19 is formed in the aeration member 2, for example in the form of a cavity provided between the piezoelectric ceramic 5 and the perforated grid 7. The aeration member 2 comprises for this purpose one or more walls 20 for delimiting the supply chamber 19. In the illustrated example, the feed chamber 19 has a generally cylindrical general shape.

 This feed chamber 19 is connected to at least two nebulization liquid circulation channels, the circulation of the nebulizing liquid being shown schematically by the arrows 21 in the figures. The supply chamber 19 thus makes it possible to generate a nebulization liquid blade, here a water layer, between the piezoelectric ceramic 5 and the perforated grid 7. According to the arrangement of the elements in FIG. nebulization, such as water, circulates substantially vertically. The nebulization liquid circulation channels are intended to be connected to at least one reservoir (not shown) of the nebulizing liquid and optionally at least one pumping device to allow the circulation of the nebulizing liquid.

 In addition, there is provided a sealing means 23 arranged between the supply chamber 19 and the piezoelectric ceramic 5, more precisely between the supply chamber 19 and the first face 5a of the piezoelectric ceramic 5 opposite the feeding chamber 19.

 According to the example illustrated in FIG. 3, the sealing means 23 is arranged on the periphery of the piezoelectric ceramic 5, more precisely of the first face 5a of the piezoelectric ceramic 5.

 The sealing means 23 is for example made in the form of a seal, in particular an O-ring.

Furthermore, the nebulizing head 3 advantageously comprises power supply means 25, such as electrical cables 25, for the electrical supply of the piezoelectric ceramic 5. These electric cables 25 are visible in FIG. Electrical cables 25 may be connected to the vehicle electrical network or alternatively to an independent energy storage means.

 As illustrated in FIG. 3, the electrical cables 25 are advantageously arranged on the same face of the piezoelectric ceramic 5, here on the second face 5b of the piezoelectric ceramic 5 opposite to the first face 5a of the piezo ceramic. 5 opposite the supply chamber 19.

The sealing means 23 is thus arranged on the side of the first face 5a of the piezoelectric ceramic 5 and the electrical cables 25 for the power supply of the piezoelectric ceramic 5 are provided on the opposite second face 5b.

 This ensures the supply of nebulizing liquid through this supply chamber 19 on one side of the piezoelectric ceramic 5 and the power supply of the piezoelectric ceramic 5 on the other side while ensuring a tightness between the two sides. The jet of droplets can be expelled through the perforations or micro-perforations of the perforated grid 7 fixed, because of the vibrations generated by the piezoelectric ceramic 5 which push or expel the nebulizing liquid through the perforated grid 7 which remains fixed. Indeed, the piezoelectric ceramic 5 behaves like a piston which makes it possible to push the liquid through the perforated grid 7 perpendicularly to the circulation movement of the nebulization liquid illustrated by the arrows 21 according to the particular example of FIG. With reference to the arrangement of the elements in FIG. 3, the piezoelectric ceramic 5 of the nebulizing head 3 generates a substantially horizontal vibratory movement.

Thus, a nebulizing head 3 with a fixed perforated grid 7 is more resistant to external aggression, such as a passenger finger of a motor vehicle that would touch the perforated grid 7 of the nebulizing head 3 accessible from the outside. the air refreshing device 1. The fixed arrangement of the perforated grid 7 and no longer able to vibrate as in the solutions of the prior art with vibrating membranes, does not interfere with nebulization since it is the vibratory movement of the piezoelectric ceramic that expels the nebulizing liquid through the perforations of the perforated grid 7 to deliver the droplets of nebulized liquid in the passenger compartment of the vehicle.

 In addition, the nebulizing head 3 is very compact and its integration into an aerator member 2 for refreshing an air flow to the passenger compartment of the vehicle is facilitated.

 Moreover, such a nebulizing head 3, devoid of a vibrating membrane and therefore a piezoelectric transducer for amplifying the vibration towards a vibrating membrane, guarantees a sufficient flow rate for cooling the flow of air F to the passenger compartment of the vehicle. vehicle by nebulization of liquid droplets delivered in this flow of air F.

Claims

An air cooling device (1) for a motor vehicle, comprising:

an airing member (2) configured to diffuse an air flow (F) towards the passenger compartment of said vehicle, and

 a nebulizing head (3) configured to deliver droplets of nebulized liquid into the air flow (F) to the passenger compartment of said vehicle, and comprising a piezoelectric ceramic (5) capable of generating a vibratory movement ,

characterized in that the nebulizing head (3) further comprises a perforated grid (7) arranged fixed and through which the nebulized liquid droplets, generated by the vibratory movement of the piezoelectric ceramic (5), are adapted to to be delivered.

Air freshening device (1) according to the preceding claim, wherein the perforations of the perforated grid (7) have a diameter of the order of 5μιη to 15μιη, preferably of the order of 8μιη to 12μιη.

Air freshening device (1) according to one of the preceding claims, wherein the piezoelectric ceramic (5) is separated from the perforated grid (7) and is arranged opposite the perforated grid (7).

Air freshening device (1) according to one of the preceding claims, wherein the piezoelectric ceramic (5) and the perforated grid (7) are concentric.

Air cooling device (1) according to any one of the preceding claims, wherein the piezoelectric ceramic (5) is formed as a disk diameter of the order of 10mm.

Air freshening device (1) according to any one of the preceding claims, wherein the perforated grid (7) is made under disc shape with a diameter of about 10mm.

7. Air freshening device (1) according to any one of the preceding claims, wherein the perforated grid (7) has a thickness of about 1mm.

8. Air freshening device (1) according to any preceding claim, wherein the nebulizing head (3) is mounted on the aeration member (2), for example arranged substantially in the center of the aeration member (2).

9. Air freshening device (1) according to any one of the preceding claims, comprising a supply chamber (19) in nebulizing liquid of the nebulizing head (3), the feed chamber (19). in nebulizing liquid being arranged between the piezoelectric ceramic

(5) and the perforated grid (7).

10. The air cooling device (1) according to the preceding claim, wherein the piezoelectric ceramic (5) is arranged upstream of the supply chamber (19) in nebulizing liquid in the direction of flow of the droplets of nebulized liquid, and the supply chamber (19) in nebulizing liquid is arranged upstream of the perforated grid (7) in the direction of flow of the nebulized liquid droplets.

11. Air freshening device (1) according to claim 8 taken in combination with one of claims 9 or 10, wherein the supply chamber (19) of nebulizing liquid is arranged in the body of aeration (2).

Air freshening device (1) according to any one of claims 9 to 11, comprising a sealing means (23) arranged between the supply chamber (19) and the piezoelectric ceramic (5). .

13. Air freshening device (1) according to the preceding claim, wherein the piezoelectric ceramic (5) has a first face (5a) and a second face (5b) opposite the first face (5a), and wherein the sealing means (23) is arranged on the side of the first face (5a) and power supply means (25) of the piezoelectric ceramic (5) are provided on the second face (5b).

Nebulizing head (3) for an air cooling device (1) according to any one of the preceding claims, comprising a piezoelectric ceramic (5) capable of generating a vibratory movement, characterized in that it further comprises a perforated grid (7) fixedly arranged and through which droplets of nebulized liquid, generated by the vibratory movement of the piezoelectric ceramic (5), are able to be delivered.