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    • 专利摘要:
    This device comprises a hollow body defining a generation chamber, means for generating droplets from a liquid jet (J) flowing inside said chamber, means for discharging a major part liquid jet, as well as means for diffusing droplets of a mist, formed from said jet. According to the invention: the generation chamber comprises an upstream chamber (5) called a common chamber, intended for the flow of both the liquid and the mist droplets, this chamber extending axially with reference to the chamber, the diffusion means comprise at least one diffusion branch (6, 7) extending obliquely from the chamber, both radially outwardly of this chamber and axially opposite the nozzle, top view. The invention provides great compactness to the device of the invention, since the dimensioning of the latter takes into account that the fine drops are generated over a short axial distance at the outlet of the nozzle. Furthermore, the device according to the invention can advantageously be put into operation, even in the absence of ventilation means.
    公开号:FR3070879A1
    申请号:FR1758339
    申请日:2017-09-11
    公开日:2019-03-15
    发明作者:Nicolas Decorde;Michel Gschwind;Frederic Richard;Yves Rousseau;Vincent Feuillard;Stephane Petit
    申请人:Areco Finances et Technologie ARFITEC SAS;
    IPC主号:
    专利说明:

    DEVICE FOR GENERATING DROPLETS FROM A LIQUID COMPRISING IMPROVED FOG DIFFUSION MEANS, AND ITS IMPLEMENTING METHOD
    Technical field of the invention
    The invention relates to devices, more particularly of small size, capable of generating a mist of micro-droplets of a liquid, for example water, in order to cool the atmosphere. The invention finds its main application in such devices, which can be mounted in a vehicle to humidify and refresh the air and make it pleasant to breathe. However, these devices can also be installed in other environments, such as on a stall to humidify and refresh fresh products displayed for sale. They can also be used to provide humidity control in confined spaces.
    State of the art
    Patent EP 0 691 162 describes a nebulization device equipped with a concentration nozzle, in which a piezoelectric element immersed in water generates a mist of water droplets at the outlet of the above-mentioned nozzle. The fog, which is then carried away by a draft generated by a fan, is extracted into the atmosphere via a diffusion orifice. This nozzle is arranged vertically, with the focusing outlet pointing upwards. This characteristic is disadvantageous, insofar as it is costly in energy, since nebulization is carried out against the weight of the liquid present in the nozzle.
    There is also known, for example from EP 0 782 885, a device the nozzle of which has a focusing outlet generally directed downwards. This nebulization device has a fan, located at approximately the same altitude as the piezoelectric element. In operation, the mist coming out of the nozzle is deflected by a deflector, then is carried away by the air flow created by the fan. The diffusion port is located approximately to the right of the nozzle outlet, below the nozzle.
    This known nebulization device however has certain drawbacks. Indeed, the nozzle necessarily has a vertical position, with its outlet facing downward, which is not always convenient. This device is also of a relatively complex structure, in particular in that it has a high number of constituent elements. In addition, it can cause hygiene problems, due in particular to a phenomenon of liquid stagnation. This nebulization device also implies a relatively high dead volume of liquid. In addition, it has been noted that possible leaks of liquid, in service, are difficult to identify. Finally, the nebulization produced by this device is not of good quality in all functional situations, in particular when the device is used in an environment undergoing strong accelerations, such as for example a motor vehicle.
    The Applicant has proposed, by FR 3 023 735, a nebulizer in which the axis of the nozzle is inclined relative to the horizontal, along an axis typically less than 30 °. A collection tank is provided, as well as a drain tube extending along the axis of the nozzle, which is therefore also inclined. In service, a mixture of liquid and droplets, intended to form a mist, flow into the aforementioned tube. The liquid is returned to the collection tank, without reaching the outlet of the tube, while the mist is extracted from the tube towards the environment to be cooled. This document provides for the use of a fan which directs an air flow, either perpendicular to the liquid jet, or parallel to it.
    Although the device known from FR 3 023 735 is generally satisfactory, it nevertheless has certain drawbacks. Indeed, the flow tube has a substantial length, which is disadvantageous in terms of overall size of the device. In addition, the configuration of this nebulizer is relatively fixed in space, so that it cannot be easily installed in all types of environment. Finally, this device necessarily involves using ventilation means, just like the devices disclosed in EP 0 691 162 and EP 0 782 885.
    In general, there is a need for droplet generation devices, capable of operating satisfactorily when they are placed in a so-called disturbed environment, namely subjected to accelerations in the different directions of space. Mention will in particular be made of land vehicles, in particular motor vehicles, but also air or sea vehicles. Furthermore, the droplet generation devices used on stalls must also meet these constraints. Indeed, a stall can also be disturbed by shocks and other mechanical disturbances, insofar as it is surrounded by people likely to come into mechanical contact with it.
    That said, the present invention proposes to remedy the various drawbacks of the prior art mentioned above. It therefore aims to propose a device for generating droplets which has a compact structure, in particular along the axial direction of the jet of liquid. The invention also aims to provide such a device, which is capable of operating in the absence of ventilation means.
    The invention also aims to provide such a device, which can be installed in different configurations. The invention also aims to propose such a device which is capable of guaranteeing satisfactory generation of droplets even in a disturbed environment, namely when it is subjected to significant accelerations according to the different dimensions of the space. Finally, the invention aims to propose such a device for generating droplets, which offers satisfactory adjustment precision, as well as reliable control.
    Objects of the invention
    To this end, the invention firstly relates to a device for generating droplets from a liquid (I; II; III; IV; V; VI; VII) comprising:
    a hollow body (1; 101; 201; 301; 401; 501; 601) delimiting a generation enclosure, means (20, 22; 120; 220; 320; 420; 520; 620) for generating droplets from a jet of liquid (J) flowing inside said enclosure, means (8; 108; 208; 308; 408; 508; 685) for evacuating a major part of the jet of liquid,
    - as well as means (6, 7; 106, 107; 206, 207; 306, 307; 406, 407; 506, 507) for diffusing droplets of a mist, formed from said jet, said generation device being characterized in that the generation enclosure comprises an upstream chamber (5; 105; 205; 305; 405; 505), known as the common chamber, intended for the flow of both liquid and mist droplets, this chamber s extending axially with reference to the enclosure, the diffusion means comprise at least one diffusion branch (6, 7; 106, 107; 206, 207; 306, 307; 406, 407; 506, 507), each branch s 'extending obliquely from the chamber, both radially outwards from this chamber and axially downstream, when viewed from above.
    According to other characteristics of the invention:
    this device is an acoustic fountain generator, this device is a nebulization device (I; II; III; IV; V; VI; VII), in which the generation means comprise a nebulization nozzle (20; 120; 220;
    320; 420; 520; 620) provided with at least one liquid inlet orifice (23; 623) and at least one liquid outlet orifice (21; 621), said nozzle being capable of generating a jet of liquid (J) at the interior of said nebulization enclosure, and a piezoelectric element (22), provided opposite said outlet orifice of said nozzle, capable of emitting acoustic waves in said liquid; and the common chamber extends axially from said nozzle, in top view, the so-called characteristic angle (a6, a7), formed by the main axis (A1) of the hollow body (1) and the characteristic axis (A6, A7) of a respective branch, is between 5 and 60 °, in particular between 10 and 40 °, in particular close to 30 °, the length (L5) of the common chamber (5) is between 50 and 300 millimeters, in particular between 100 and 200 millimeters, in particular close to 150 millimeters, the longitudinal entry section (S64, S74) of each branch is between 30 and 150 millimeters, in particular between 60 and 100 millimeters, in particular close to 80 millimeters, the longitudinal inlet section (S64, S74) of each branch is equal to a fraction of the length (L5) of the common chamber (5), said fraction being between 75 and 100%, being included in especially between 85 and 90%, the cross-section in each branch decreases towards the downstream, several branches are provided, in particular an even number of branches, which are angularly distributed in a regular manner around the chamber, the evacuation means comprise an axial evacuation tube (8; 108; 208;
    308; 408; 508), extending said common chamber downstream, beyond the junction between the diffusion branch and the common chamber, the length (L8) of the evacuation tube (8) is between 10 and 100 millimeters, in particular between 20 and 50 millimeters, the passage section in the evacuation tube is substantially constant, the evacuation tube (8) is extended, downstream, by a downstream evacuation end piece (85) of decreasing section towards downstream, this discharge nozzle defining a downstream orifice (86) for discharging liquid, the diffusion means further comprise at least one diffusion nozzle (68, 78), each extending a respective diffusion branch (6 , 7), as well as removable and / or orientable connection means between this branch and this nozzle, the body (1) comprises at least one upstream teat for discharging liquid (45; 645), each teat defining an orifice ( 45 '; 645') upstream of liquid evacuation, the device further comprises ventilation means (3; 103; 203; 303; 403; 503) capable of generating a gas flow intended to entrain at least part of the liquid leaving the nozzle, in the droplet generation enclosure, these ventilation means comprising a ventilation member (31) and a ventilation channel (4 ; 104; 204; 304; 404; 504; 604), extending from said ventilation member and opening into the enclosure, an intermediate passage (44; 144; 244; 344; 444; 544; 644), the gas flow generated by the ventilation member being able to flow, in the intermediate passage, along a first flow path different from the droplet generation path, and return means (46; 646) suitable for returning the gas flow from the intermediate passage, radially towards the center of the enclosure, along a second flow path substantially identical to the droplet generation path, the upstream end of the intermediate passage (44) is located, according to the generation direction, upstream from the outlet (21) of the liquid admission member (20) into the enclosure, seen at the end, the intermediate passage (44) extends at the outer periphery of the inlet member (20), the upstream end of the intermediate passage (544; 644; 744) is located, in the direction of droplet generation, downstream of said outlet (21), the distance (D544; D644; D744) separating, in the direction of droplet generation, said outlet (521) and the upstream end (544 ') of the intermediate passage, is between 5 and 50 millimeters, in particular between 10 and 30 millimeters, in particular close to 20 millimeters, the intermediate passage (44) is delimited by the opposite walls belonging respectively to an upstream neck (12) and to a downstream barrel (11) of cross section smaller than that of the neck, the cross section of the barrel (11) is greater than the external section of the intake member (20), the transverse dimension or height (H44) of the intermediate passage, is between 5 and 20 millimeters, in particular close to 10 millimeters, the barrel (11) and the neck (12) are coaxial and delimit an intermediate passage of annular shape, the return means comprise by said return elements (46) having a rounded shape, the concavity of which faces backwards, in longitudinal section, seen from the front, the return walls form a crown (46) situated at the outer periphery of the member 'inlet (20), the inner edge (47') and the outer edge (47 ”) of said crown being located on either side of the inner edge (44”) of the intermediate passage (44), the ventilation channel comprises an upstream section (41), provided immediately at the outlet of the ventilation member, the air flow paths, respectively in the upstream section and in the intermediate passage, being mutually different, the intermediate passage defines a path air flow, the air flow direction is substantially identical to the generation direction and whose air flow direction is opposite to the generation direction, the ventilation means comprise a module ventilation, and there are provided fixing means, in particular removable from the ventilation module on the body of said device, the hollow body is hollowed out with a lateral cut delimiting a seat, intended for the reception of a fitting belonging to the means of ventilation, the device has no ventilation means.
    The subject of the invention is also a method of implementing a device such as the above, in which:
    liquid is admitted into the enclosure, said liquid is made to flow into the common chamber, and a mist of droplets formed from said liquid, a majority of so-called droplets flow into each diffusion branch fines, the size of which is less than a predetermined value, a fraction of the liquid not transformed into droplets and, possibly, so-called large droplets, the size of which is greater than said predetermined value, is discharged by the evacuation means.
    It is to the credit of the inventors for having observed and understood certain physical phenomena, underlying the formation of the mist by a device for generating droplets. In fact, they have identified in particular that the fine drops, which are the most advantageous for forming a good quality mist, are generated over a small axial distance at the outlet of the nozzle. In other words, most of these fine drops are produced after a short distance, of the order of ten centimeters for conventional operating parameters of the device.
    Consequently, the invention confers a great compactness on the droplet generation device, since the dimensioning of the latter takes account of the existence of this length, called useful length. By comparison, the prior art generally provides for devices of large axial dimension. Under these conditions, their downstream area is detrimental in terms of size, without being effective in terms of fog formation.
    The structure of the device according to the invention reflects the physical phenomenon, as described above. This device firstly comprises a common chamber, the length of which advantageously corresponds to the aforementioned useful length. This common room is advantageously extended, opposite the nozzle, by a central liquid evacuation tube, as well as by at least one radial branch.
    Each branch is intended to collect the major part of the fine drops, created in the common room, then to diffuse them in the target environment. It will be noted that the orientation of each diffusion branch advantageously has both a radial component and an axial component, with reference to the direction of the common chamber. This makes it possible to avoid any significant change in direction of the fine drops, such as a U-turn as provided in certain previous solutions, in particular when the branches of the device according to the invention extend forward.
    In this way, the shocks of fine drops against possible walls are reduced, which has a double advantage. On the one hand, the fog formation efficiency is high. In addition, the kinetic energy of the drops is preserved, along its path towards the exit of each diffusion branch. Consequently, the device according to the invention can advantageously be put into service, even in the absence of ventilation means.
    The above advantages, as well as other advantages of the invention, will appear more clearly on reading the description below.
    Description of the figures
    Figures 1 to 22 illustrate embodiments of the invention, but do not limit the scope of the invention.
    Figure 1 is an exploded perspective view, illustrating the various components of a droplet generation device according to a first embodiment of the invention, this droplet generation device being a nebulization device in the example illustrated;
    Figures 2 and 3 are perspective views from two different angles, illustrating the nebulization device according to the invention.
    Figures 4 and 5 are longitudinal sections, illustrating the nebulization device of the previous figures respectively viewed from the side and from above.
    Figure 6a is a longitudinal section in side view, similar to Figure 4 but on a larger scale, illustrating more particularly the air return means belonging to the nebulization device according to the invention.
    Figure 6b is a front view, along arrow 6b of Figure 6a illustrating the nozzle and the air return means of the device.
    Figure 7 is a longitudinal section in top view, similar to Figure 5 but on a larger scale, illustrating more particularly certain geometric characteristics of the nebulization device according to the invention.
    Figures 8 and 9 are longitudinal sections similar to Figures 4 and 5 respectively, showing the flow of air, liquid and mist droplets inside the nebulization device according to the invention.
    Figure 10 is a perspective view, similar to Figure 2, illustrating a first alternative embodiment of the nebulization device, as regards the air intake.
    FIG. 11 is a longitudinal section in side view, similar to FIG. 4, illustrating the nebulization device of FIG. 10.
    Figure 12 is a perspective view, similar to Figure 2, illustrating a second alternative embodiment of the nebulization device, as regards the air intake.
    FIG. 13 is a longitudinal section in side view, similar to FIG. 4, illustrating the nebulization device of FIG. 12.
    Figure 14 is a perspective view, similar to Figure 2, illustrating a third alternative embodiment of the nebulization device, with regard to the air intake.
    FIG. 15 is a longitudinal section in side view, similar to FIG. 4, illustrating the nebulization device of FIG. 14.
    FIG. 15a is a perspective view with cutaway, illustrating the nebulization device of FIGS. 14 and 15.
    Figure 16 is a perspective view, similar to Figure 2, illustrating a fourth alternative embodiment of the nebulization device, with regard to the diffusion of mist droplets.
    FIG. 17 is a longitudinal section in side view, similar to FIG. 8, illustrating the nebulization device of FIG. 16.
    Figure 18 is a longitudinal section in side view, similar to Figure 17, illustrating a fifth alternative embodiment of the nebulization device, with regard to the diffusion of mist droplets.
    Figure 19 is a perspective view, similar to Figure 2, illustrating a sixth alternative embodiment, in which the nebulization device according to the invention has improved ventilation means.
    FIGS. 20 and 21 are views respectively in longitudinal section from the side and from above, illustrating the nebulization device of FIG. 19.
    FIG. 22 is a longitudinal section in side view on a larger scale, similar to FIG. 6a, illustrating the upstream part of the nebulization device of FIGS. 19 to 21.
    The following reference numbers are used in the present description:
    I Fogging device 1 Hollow body A1 Axis of 1 11 barrel 12 Collar 11 ' Upstream end of 11 13 Cut out of 12 14 Front opening 15 Closure flange 16 O-ring 17 stud 18 seating 20 buzzard 21 Outlet of 20 22 Piezoelectric element 24 Support of 22 23 20 intake ports 21 Outlet of 20 3 Ventilation module 31 Ventilation device 32 Air filter 33 Air injection device 34 Connection 35 edges 4 Ventilation channel 41 Upstream section of 4 42 Downstream section of 4 44 Annular passage 45 Nipple 45 ' 45 hole 46 Return walls 47 ', 47 " Edges of 46 48 Rear end of 46 5 Common room 51.52 Entry / Exit of 5 S5 Section of 5 L5 Length of 5 AT 5 Longitudinal axis of 5 T5 Cross axis of 5 60,70 Side notches 6.7 branches 61.71 Upstream walls of 6.7 62.72 Downstream walls of 6.7 64.74 Entry of 6.7 65.75 Midpoint of 6.7 66.76 6.7 out A6, A7 6.7 axis S64.S74 Entrance section of 6.7 S65.S75 6.7 midsection D61.D71 Distance between 21 and 61.71 68.78 Diffusion tip 69.79 Diffusion hole 8 Drain tube 81.82 Entry / Exit of 8 S8 Section of 8 L8 Length of 8 85 Drain tip 86 Evacuation port F1-F3 Air flow G1.G2 Drip flow II Fogging device 101 Hollow body 115 Closure flange 120 buzzard 103 Ventilation module 104 Ventilation channel 141 Upstream section of 104 142 Downstream section of 104 144 Annular passage 134 Connection 105 Common room 106,107 branches 108 Drain tube 185 Drain tip 186 Evacuation port III Fogging device 201 Hollow body 215 Closure flange 220 buzzard 203 Ventilation module 204 Ventilation channel
    241 Upstream section of 204 242 Downstream section of 204 244 Annular passage 234 Connection 205 Common room 206,207 branches 208 Drain tube 285 Drain tip 286 Evacuation port IV Fogging device 301 Hollow body 315 Closure flange 320 buzzard 303 Ventilation module 304 Ventilation channel 341 Upstream section of 304 342 Downstream section of 304 344 Annular passage 334 Connection 305 Common room 306.307 branches 308 Drain tube 385 Drain tip 386 Evacuation port V Fogging device 401 Hollow body 415 Closure flange 420 buzzard 403 Ventilation module 404 Ventilation channel 441 Upstream section of 404 442 Downstream section of 404 444 Annular passage 434 Connection 405 Common room 406.407 branches 408 Drain tube 485 Drain tip 486 Evacuation port VI Fogging device 501 Hollow body 515 Closure flange 520 buzzard 503 Ventilation module 504 Ventilation channel 541 Upstream section of 504 542 Downstream section of 504 544 Annular passage 534 Connection 505 Common room 506.507 branches 508 Drain tube 585 Drain tip 586 Evacuation port VII Fogging device 620 buzzard 621 Exit from 620 623 620 intake ports 611 barrel 612 Collar 611 ' End of 611 604 Ventilation channel 641 Upstream section of 604 642 Downstream section of 604 644 Annular passage D644 Distance between 621 and 644 ’ 644 ' End of 644 206,207 branches 645 Nipple 645 ' Port of 645 646 Return walls 647 ', 647 " Edges of 646 648 Rear end of 646 685 Evacuation chute 686 Evacuation port
    detailed description
    Figures 1 to 9 illustrate a droplet generation device according to a first embodiment of the invention, which is by way of non-limiting example a nebulization device generally designated by the reference I. This device I comprises first of all an elongated hollow body 1, which delimits a nebulization enclosure. A1 is the main longitudinal axis of this body and of this enclosure, which corresponds to the axis of the nozzle fitted to the device, as will be seen below. This main axis A1 is substantially horizontal, in the example illustrated. However, as will be explained below, this axis can be oblique or vertical. In what follows the terms "front" and "rear", synonyms of the terms respectively "downstream" and "upstream", are defined with reference to the flow of fluid in the hollow body.
    The body has a main barrel 11 and a secondary neck 12, of larger cross section, extending rearward from the main barrel. This barrel and this neck, which are cylindrical with a generally circular section, are concentric in the example illustrated and both extend along the main axis A1 above. We note 11 ’the upstream end, namely adjacent to the nozzle 20, of the barrel 11. This end 11’ is located upstream, namely behind, with respect to the outlet of this nozzle. This allows the device of the invention to be very compact, according to the main direction A1.
    The neck 12 is hollowed out with a lateral cut 13, extending over part of the periphery of this neck. In the example illustrated, this cutout extends approximately over half of the neck, an angular sector of approximately 180 °. This cut allows to define a seat for the reception of ventilation means, described in more detail below. It will be noted that this cutout is formed overall on the upper part of the body 1, which makes it possible to prevent the water from escaping by gravity, outside the interior volume of this body. This neck 12 is further provided with a rear rear opening 14, closed by means of a closing flange 15 with interposition of an O-ring 16. This flange is pierced with a hole, in which a nozzle extends of concentration 20, of a type known per se.
    The nozzle 20 has an internal side wall, which delimits an interior volume capable of containing the liquid to be sprayed. The internal cross section of this wall has a gradual narrowing in the direction of a liquid outlet orifice 21. Opposite this orifice 21, the abovementioned interior volume is closed by a piezoelectric (ceramic) element 22, associated with a support 24. The aforementioned flange 15 is further provided with a stud 17, of a type known per se, which can be connected to a pipe, not shown, intended for supplying liquid towards the interior volume of the nozzle 20.
    Element 22 is capable of emitting acoustic waves into the liquid. The internal wall of said nozzle is typically made of a hard material capable of reflecting the acoustic waves generated by said piezoelectric element 22. Such a material typically has an acoustic impedance, which is sufficiently different from that of water in order to reflect the acoustic waves. The converging shape of the internal walls of the nozzle 20 is determined so as to focus the ultrasonic acoustic waves at a location close to the central part of the outlet orifice 21. This makes it possible to generate a mist of micro-droplets from the liquid to be sprayed when the nozzle is filled with liquid and when the ceramic 22 emits acoustic waves of appropriate frequency and intensity. The converging shape of the internal walls of the nozzle is advantageously parabolic, which improves the efficiency. Preferably, the shape of the internal walls of the nozzle 20 shows a radial symmetry.
    Generally, the piezoelectric ceramic element 22 is preferably of cylindrical shape, typically a plate of circular shape. By way of nonlimiting example, it may have a diameter between 10 mm and 30 mm, in particular between 20 mm and 25 mm. The outlet 21 preferably has a circular shape. In one embodiment, its diameter is between 2 and 10 mm, and advantageously between 4 and 6 mm. The internal height of the nozzle is typically between 20 mm and 50 mm, typically close to 30 mm, knowing that this distance corresponds to the near field of ultrasound generated by the piezoelectric ceramic 22.
    In known manner, the nozzle 20 has at least one liquid intake orifice allowing the liquid to be sprayed to be admitted into the interior volume of the nozzle. One can in particular provide liquid admission holes, or else a vertical offset of the nozzle, maintained by a first end, which allows an annular admission of liquid over the whole part located at the opposite end of this nozzle. Preferably, a plurality of inlet openings are arranged around the longitudinal axis of the nozzle, in an area close to the piezoelectric ceramic element. In the present exemplary embodiment, there are four admission orifices 23 regularly distributed around the periphery of the nozzle. The inlet section of the nozzle 20, namely the sum of the surfaces of the inlet orifices, is advantageously greater than the section of the outlet orifice, preferably at least three times greater, in order to prevent a lack of water and avoid cavitation in the nozzle.
    In a manner known per se, the external lateral wall of the nozzle defines, with the facing faces of the body, a pressurization zone for the liquid. In service, the latter is permanently filled with liquid, which guarantees optimal operation of the piezoelectric element, even under disturbed conditions. In addition, this pressurization zone communicates with the interior volume of the nozzle, via the inlet orifices 23. The presence of the flange 15 is advantageous, since it first of all allows the pressurization zone to be closed. pressure with a particularly satisfactory seal. In addition, it provides a removable attachment of the piezoelectric element, which can therefore be replaced simply and quickly.
    This pressurization zone is supplied with liquid by means of the aforementioned stud 17, from a collection volume not shown. The geometry, dimensions and location of this collection volume are chosen according to the environment, known as the target, in which the nebulization device according to the invention is installed. The circulation of liquid, from the collection volume towards the pressurization zone, is conventionally provided by at least one pump of known type, which is also not shown in the figures.
    The frequency of ultrasound is advantageously between 1.3 MHz and 3 MHz, in particular between 1.7 MHz and 2.4 MHz. The piezoelectric element can typically absorb a large electrical power, a fraction of which is rendered in the form of acoustic energy transmitted to the liquid, the rest being dissipated in thermal form. It will be noted that, in service, the piezoelectric element is constantly covered by the liquid which prevents its deterioration by overheating.
    When the piezoelectric element 22 runs dry even for a very short time, it may be damaged or even destroyed. To avoid this, means are advantageously provided for preventing said piezoelectric element from functioning (ie does not emit acoustic waves or only very low power acoustic waves) when the piezoelectric element is not immersed in the liquid to be sprayed. These means, which are not shown in the figures, can take different forms.
    In general, at least one means of detecting the lack of liquid and / or a means of detecting the heating of the piezoelectric element and a means of feedback on the electrical supply of said piezoelectric element can be provided. Said means of detecting the lack of liquid can be a level sensor, an ultrasonic sensor, or a presence sensor which cuts or regulates the operation of the piezoelectric element. This sensor can be an optical sensor or a capacitive sensor or even an inductive sensor. This sensor can be placed in any suitable location, in the nebulization device or at its periphery.
    Said means of detecting the lack of liquid can be a sensor which detects the presence of the jet of liquid at the outlet of the outlet orifice of the nozzle. This means is less preferred since it causes a delay in the detection of an immersion fault of said piezoelectric element. Said means for detecting the lack of liquid can be a pressure sensor in the nozzle and / or at the outlet of the circulation pump. Another means for detecting the lack of liquid in the nozzle is a temperature detector on the surface and / or inside of said piezoelectric element, which makes it possible to detect rapid heating of said piezoelectric element before it has suffered significant damage.
    The ventilation means are produced in the form of a ventilation module 3, which can be fixed, in particular removably, to the seat formed by the edges of the cutout 13, formed in the neck 12. This module comprises an active member ventilation 31, or fan, of a type known per se, which is capable of blowing a gas flow, typically air. This module further comprises an air filter 32, also of the conventional type. The module 3 finally comprises an air injection member 33, which makes it possible to channel the air coming from the fan 31, towards the interior volume of the body 1.
    This member 33 is provided with a connector 34, having the shape of a semicircle in front view. This connector 34 is suitable for being pressed against the edges of the cutout 13, with the interposition of sealing means not shown. To this end, flanges 35, present at the two lateral ends of the connector 34, are fixed on studs 18, forming seats, provided on the outside face of the neck 12. The mutual fixing between the connector 34 and the studs 18 of the body 1 is advantageously removable, in particular by means of screwing means, not shown. By way of nonlimiting example, provision may be made for using a screw passing through the stud 18, which is screwed into the fitting 34 at the level of threaded holes, formed in the flange 35. As a variant, it is possible to provide any type of fastening means, in particular any type of removable type fastening means.
    As shown in particular in FIGS. 4 and 8, the fan blows air in service through a so-called ventilation channel 4, formed in the injection member 33. This channel has a straight upstream section 41, which s' extends axially above the upper face of the main barrel. This upstream section is extended into a downstream section 42, which extends along a portion of a crown inside the fitting 34. This downstream section finally opens into an annular passage 44, delimited by the walls opposite the neck 11 and the was 12. As will be seen in what follows, this passage 44 opens into the nebulization enclosure. Furthermore, the neck 12 is equipped with a nipple 45 defining an upstream evacuation orifice 45 ’, the function of which will be specified in the following.
    The nebulization device further comprises return means, making it possible to modify the direction of flow of the gas flow from the annular passage towards the vicinity of the nozzle. These deflection means, which are illustrated in particular on a larger scale in FIGS. 6a and 6b, include so-called deflection walls 46. Viewed from the front, as shown in FIG. 6b, these walls 46 form a crown of which there is noted 47 ′ and 47 ”the edges respectively radially inside and outside. In longitudinal section, as shown in FIG. 6a, these return walls having a rounded shape, the concavity of which faces backwards.
    We note 48 the rear end of this crown 46, and we note that the inside edge 47 ’is located behind the outside edge 47”. Furthermore, seen from the front, this inner edge 47 'and this outer edge 47 ”are located on either side of the inner edge 44” of the passage 44, which corresponds to the outer face 11 ”of the barrel 11. As shown in FIG. 6b, this deflection ring 46 is situated on the periphery of the nozzle 20. The shape of these deflection walls makes it possible to reduce the sharp edges and, consequently, to limit the disturbances of the air flow as well as the turbulences.
    Advantageous dimensional values characteristic of the nebulization device according to the invention are as follows (see FIGS. 6a and 6b):
    - The passage section, or height H44, of the intermediate passage is between 5 and 20 mm, in particular close to 10 mm.
    - The cross section or height H11 of the barrel, at its upstream end, is between 25 and 55 mm, in particular between 30 and 40 mm.
    As illustrated in particular in FIG. 7, the longitudinal axis of the nozzle 20 is substantially parallel to the main axis A1 of the body, namely that it is generally horizontal in the example illustrated. According to the invention, it can be provided that this longitudinal axis is inclined relative to the horizontal, even vertical. Preferably, this axis of the nozzle forms, with respect to the horizontal, an angle between -30 ° and + 30 °, in particular between -15 ° and + 15 °. The value of this angle is considered "at rest", that is to say when the device according to the invention is mounted on a support, such as a vehicle or a stall, which rests on a horizontal ground in the absence of dynamic disturbance.
    Referring again to the exploded perspective of Figure 1, the barrel 11 of the body 1 is hollowed out of two lateral notches 60 and 70, from which extend two branches 6 and 7. The latter can be made in one holding with the barrel, or one can provide removable fixing means, of any suitable type as in particular by snap-fastening, between the walls of the notches and the respective branches. In the case where the branches 6 and 7 are removably fixed, the fixing means must be sealed.
    There are 61 and 71 the walls of the branches 6 and 7, which are adjacent to the nozzle 20. These walls 61 and 71 are called upstream, with reference to their positioning relative to the nozzle, or even exterior with reference to the volume of each plugged. 62 and 72 are also noted the walls of the branches 6 and 7, which are opposite to the nozzle 20. These walls 62 and 72 are called downstream, with reference to their positioning relative to the nozzle, or even interior with reference to the volume. of each branch.
    These branches 6 and 7 delimit different functional regions of the nebulization enclosure, belonging to the nebulization device I according to the invention:
    an upstream chamber 5, or common chamber, intended for the flow of the liquid and of droplets formed from this liquid. We note 51 the entry of this chamber, which corresponds to the exit of the nozzle 20, and 52 the exit of this chamber, which corresponds to the junction between each downstream wall 62, 72 of each branch 6, 7 and the barrel 11 We denote S5 the passage section of this chamber, in a direction perpendicular to the main axis A1. This section S5, which is substantially constant in the example illustrated, is equal to the value H11 described above, namely between 25 and 55 mm, in particular between 30 and 40 mm. The length L5 of this chamber, which corresponds to the distance between its inlet and its outlet along the axis A1, is advantageously between 50 and 500 mm, in particular between 50 and 150 mm, advantageously between 75 and 125 mm, in particular neighboring 100 mm, a so-called evacuation tube 8, coaxially extending the chamber 5 opposite the nozzle 20. This tube is intended for the flow of non-nebulized liquid, to which is possibly mixed a fraction of drops of large size, also called large drops. We denote S8 the passage section of this tube, in a direction perpendicular to the main axis A1. This section S8 is advantageously close to that S5 of said chamber. We note 81 the inlet of this tube, which corresponds to the outlet 52 of the chamber, and 82 the outlet of this tube. The length L8 of this tube, which corresponds to the distance between its inlet and its outlet along the axis A1, is advantageously between 10 and 50 mm, in particular between 10 and 30 mm, in particular close to 20 mm, a nozzle 85 said discharge extends the tube 8, opposite the chamber 5. This nozzle 85 can be, according to a first embodiment, made in one piece with the tube 8. Preferably, means can be provided removable fixing, of any suitable type such as by snap-fastening, between these two mechanical elements, as long as this connection is sealed. This nozzle is terminated by an orifice 86, known as an orifice. The passage section of the end piece decreases, preferably continuously, in the direction of this terminal orifice 86.
    This orifice is placed in communication with a pipe, not shown, ensuring in a known manner the evacuation of the liquid towards the collection volume. Typically the section of the orifice 86, which corresponds to that of the above-mentioned pipe, is close to 10 mm. This ensures good gravity drainage of the liquid, at the nominal operating flow rate of the pump ensuring the circulation of this liquid.
    Each branch 6, 7 extends obliquely, namely on the one hand radially outward from the chamber 5 and, on the other hand, axially downstream, that is to say the opposite of the nozzle 20. The above geometric terms refer to a so-called top view, that is to say perpendicular to a plane extending from rear to front of the entire device. Each branch is intended for the flow essentially of small droplets, also called fine drops. We note 64, 74 its entry, which corresponds to the midpoint between the opposite faces of its outer and inner walls, along the longitudinal axis A5 (identified in Figure 7 with reference to entry 64) passing through the inner wall from the room. We denote 65, 75 its so-called median or characteristic point, which corresponds to the midpoint between the opposite faces of its outer and inner walls, along the transverse axis T5 passing through the outlet 52 of the common room 5. We denote A6 and A7 the characteristic axis of each branch, which connects its input 64, 74 to its characteristic point 65, 75.
    For each branch:
    the so-called characteristic angle a6 and a7, formed by the main axis A1 and the characteristic axis A6 or A7, is advantageously between 5 and 60 °, in particular between 10 and 40 °, in particular close to 30 °, the cross section longitudinal entry S64 or S74, namely the distance between the facing walls along the axis A1 at the level of entry 64 or 74, is advantageously between 30 and 150 mm, in particular between 60 and 100 mm, in particular close to 80 mm. This section S64 or S74 corresponds to a fraction of the length L5, between 75 and 100%, in particular between 85 and 90% of this length L5, the input cross section, namely the distance separating along the vertical axis the opposite walls of the branch at the level of the entry 64 or 74, is advantageously between 20 and 50 mm, the middle section S65 or S75, namely the distance transversely dividing the opposite walls at the point 65 or 75 , is advantageously less than the longitudinal input section S64 or S74, as defined above. This middle section is typically close to the section of the diffusion nozzle 68, 78, which will be described in the following, the distance D61 or D71, longitudinally separating the nozzle outlet and the upstream wall 61 or 71, at the level of its internal face, is advantageously between 1 and 50 mm, in particular between 5 and 20 mm.
    In FIG. 7, only the characteristic values of branch 6 have been illustrated. The characteristic values of branch 7 are identical, insofar as the two branches are mutually symmetrical with respect to the main axis A1.
    Each branch 6, 7 is extended, opposite the nozzle 20, by a respective nozzle, called diffusion nozzle 68, 78. This nozzle, which extends from the outlet of each branch, is provided with a terminal orifice 69, 79, called the diffusion orifice, through which the mist is diffused in the target environment. The dimensions and / or orientation of this nozzle are adapted to this target environment, in particular the geometry and the size of the latter. It can be provided that each endpiece is permanently fixed, or advantageously removable, relative to the branch on which it is mounted. It is also possible to provide a sealed connection, for example of the bellows type, making it possible to modify the orientation of this endpiece relative to this branch.
    The above values are considered in the rest position, as defined above. The altitudes of the orifices are taken at the center of these. The distances are taken between the facing faces of the mechanical elements considered.
    Figures 8 and 9 schematically show the operation of the nebulization device according to the invention, as described above. We first fill the collection volume, in a manner known per se. Then the circulation pump is started, so that the liquid gradually fills the interior volume of the body 1. The liquid is then admitted into the nozzle 20, via the intake orifices 23. A jet J of liquid flows then along the axis A1 from the outlet orifice 21, namely generally horizontal in the example. The piezoelectric element is then put into service, so as to generate mist droplets flowing in the interior volume of the body, as will be detailed in the following.
    The fan 31 is also actuated, typically continuously, so as to generate an air flow, the path of which is illustrated in FIGS. 6a, 8 and 9. This air first flows in the ventilation channel 4 according to the arrows F1, substantially against the current of the jet of liquid J. Then this air undergoes a first change of direction, before being admitted into the annular passage 44 according to the arrows F2. In this passage 44, the air flow path has an air flow direction substantially identical to the nebulization direction. These two directions are defined by the axis A1, namely generally horizontal in the example illustrated. On the other hand, the direction of air flow in passage 44 is opposite to the direction of nebulization, namely that the air flows from left to right in FIGS. 6a, 8 and 9, while the jet of liquid flows from right to left in these same figures.
    At the downstream end of passage 44, the air then strikes the return walls 46, described above. The rounded shape of these walls ensures a second change of direction of the air flow, without however generating too much turbulence. The air finally flows into the common chamber 5 according to arrow F3, in the vicinity of the nozzle, substantially cocurrent with the jet of liquid. It will be noted that the elementary threads of this air flow are particularly homogeneous, both in terms of direction and speed.
    The presence of the annular passage 44 and the return means 46, as described above, is advantageous. In fact, the inventors have found that, in the vicinity of the nozzle, the gas flow has very satisfactory homogeneity. In other words, all the threads making up this flow have substantially the same speed and the same direction. This creates a laminar flow of liquid and air, which helps to limit air turbulence and thus drive the fine droplets generated towards the outlet in a directionally stable manner to prevent the shock of droplets between them and on the walls of the duct.
    A mist of droplets, which is formed under the action of the piezoelectric element, is carried away by the above-mentioned air flow. This mist is formed by a mixture of so-called fine droplets, the diameter of which is less than about 5 micrometers, and of so-called large droplets, the diameter of which is greater than the latter value. In FIGS. 8 and 9, the fine droplets are illustrated by small circles, while their direction of flow is indicated by the arrows G1. In addition, the large droplets are illustrated by squares of larger dimension than that of the circles above, while their direction of flow is indicated by the arrows G2.
    The fine droplets are, for the most part, directed towards each branch 6, 7, before being diffused into the environment by the diffusion tips. As explained above, these fine drops do not undergo significant shocks against the walls, in particular thanks to the value of the angle a6, a7 formed between each branch and the common chamber 5. On the other hand, the jet of liquid J s' flows axially in the common chamber 5 then in the evacuation tube 8. This liquid is then directed, via the evacuation nozzle 85, to the outlet orifice 86 then the collection volume, before being recycled to the nozzle entrance. This liquid can be mixed with a small fraction of large droplets, which are noticeably absent inside the diffusion branches.
    The presence of the tip 85, of decreasing section downstream, has specific advantages. In fact, it makes it possible to avoid untimely obstruction of the common chamber 5, with liquid coming from the non-nebulized fraction of the jet J. This nozzle 85 advantageously cooperates in combination with the nipple 45, since the latter also performs a function of liquid evacuation. This teat finds its application in particular when the liquid tends to stagnate, in particular by gravity, also in the vicinity of the upstream part of the body 1.
    This teat 45 and this tip 85 both provide a liquid discharge function. More precisely, when the device is generally flat, the majority of the liquid is evacuated by the nozzle 85, while a smaller fraction of this liquid is evacuated by the teat 45. When the device is oriented upwards , namely that the inlet 51 of the chamber 5 is located at an altitude lower than that of its outlet 52, the vast majority of the liquid is evacuated by the teat 45 while the nozzle 85 possibly allows the evacuation of a very small fraction of this liquid. Furthermore, when the device is oriented downwards, namely that the inlet 51 is located at an altitude higher than that of the outlet 52, substantially all of the liquid is discharged through the nozzle 85.
    When the liquid level as detected by the water presence sensor is insufficient to ensure that the piezoelectric element 22 is fully submerged, a feedback loop interrupts or decreases the operation of this piezoelectric element. If this drop in level is prolonged beyond a certain duration, water is added to the interior volume of the enclosure. The addition of water can also be done permanently, continuously or discontinuously, for example using a peristaltic pump (not shown in the figures), in order to compensate for the loss of water due to the nebulization.
    According to an advantageous variant, provision may be made to measure, continuously or at regular intervals, the speed of rotation of the pump. If there is a sudden increase in this speed, this may mean that the pump is no longer running in water, but in air. In other words, the amount of liquid present in the device is insufficient. The aforementioned feedback loop acts on the piezoelectric element, in a similar way to that described in the previous paragraph.
    According to another advantageous variant, provision can be made to measure, continuously or at regular intervals, the power of the piezoelectric element. If there is a sudden change in this power, this may mean that there is a lack of water in the nozzle or in the pressurized tank. The pump flow is then adjusted so as to adjust the water flow as a function of the acoustic power (the pump flow should advantageously be increased as a function of the electric power sent to the piezoelectric element).
    Figures 10 and 11 illustrate a second embodiment of the nebulization device, according to the invention. In these figures, the mechanical elements similar to those of FIGS. 1 to 9 are assigned the same reference numbers there, increased by 100.
    The nebulization device II of this second embodiment differs from that I of the first embodiment, in particular in that its ventilation channel 104 has an upstream section 141 located behind the nozzle 120. Under these conditions, the air flows substantially cocurrently with the jet of liquid J in this section 141, before being returned radially inward by the walls of the downstream section 142. The air then opens into the annular passage 144, before be admitted to common room 105.
    Figures 12 and 13 illustrate a third embodiment of the nebulization device, according to the invention. In these figures, the mechanical elements similar to those of FIGS. 1 to 9 are assigned to them the same reference numbers, increased by 200.
    The nebulization device III of this third embodiment differs from that I of the first embodiment, in particular in that its ventilation channel 204 has an upstream section 241 extending radially outward from the body 201. In these conditions, the air flows substantially at a cross current with respect to the jet of liquid J in this section 241, before being returned towards the rear by the walls of the downstream section 242. The air then opens into the passage annular 244, before being admitted to common room 205.
    Figures 14 and 15 illustrate a fourth embodiment of the nebulization device, according to the invention. In these figures, the mechanical elements similar to those of FIGS. 1 to 9 are assigned to them the same reference numbers, increased by 300.
    The nebulization device IV of this fourth embodiment differs from that I of the first embodiment, in particular in that the ventilation channel 304 extends mainly to the outer periphery of the body 301. Seen at the end, namely along the longitudinal axis of the body in FIG. 15, this channel 304 forms a ring section, peripheral to the body 301. The downstream section 342 of this channel 304 opens into the annular passage 344 defined, in a manner analogous to the first modes of realization, by barrel 311 and neck 312.
    Figures 16 and 17 illustrate a fifth embodiment of the nebulization device, according to the invention. In these figures, the mechanical elements similar to those of FIGS. 1 to 9 are assigned to them the same reference numbers, increased by 400.
    The nebulization device V of this fifth embodiment differs from that I of the first embodiment, in particular in that it is provided with a single branch 406, extending obliquely from the barrel 411. In this example, this branch 406 is placed above the barrel, namely in the vicinity of the ventilation means 403. For this reason, it is preferred to use an air supply such as that of the device II of FIGS. 10 and 11. The value of l angle a406 is within a range of values, such as that of angle a6 described above.
    FIG. 18 illustrates a sixth embodiment of the nebulization device, in accordance with the invention. In this figure, the mechanical elements similar to those of Figures 1 to 9 are assigned the same reference numbers, increased by 500.
    The nebulization device VI of this sixth embodiment is similar to that V described immediately above, namely that it is provided with a single branch 506. The air supply is similar to that of device III of the figures 12 and 13.
    As an additional variant, not shown, one can provide more than two branches, in particular distributed angularly in a regular manner. For example, three branches can be provided, spaced two by two angularly by 120 °, or four branches spaced two by two angularly by 90 °. As an additional variant, a single branch can be provided, which extends annularly around the periphery of the flow tube.
    Figures 19 to 22 illustrate a seventh embodiment of the nebulization device, according to the invention. In these figures, mechanical elements similar to those of FIGS. 1 to 9 are assigned the same reference numbers, increased by 600.
    The nebulization device VII of this sixth embodiment differs from that I in that the upstream end 644 'of the annular passage 644 is located downstream of the outlet 621 of the nozzle 620, as shown in particular on a large scale in the figure. 22. Advantageously, the distance D644 separating, in the direction of nebulization, the outlet 621 from the nozzle 620 and the upstream end 644 'of the intermediate passage 644 is between 10 and 30 mm, in particular between 15 and 25 mm. This end 644 ’corresponds to the upstream end 61T of the barrel 611.
    This device VII also differs from that I, in that it does not have an evacuation tube extending in the extension of the common room. In device VII, the common chamber 605 is extended by an evacuation chute 685, extending transversely relative to this chamber, namely downwards in the example illustrated. This chute, of generally frustoconical shape flared upstream, is terminated by an evacuation orifice 686.
    The variant of FIGS. 19 to 22 is advantageous, in particular in terms of quality of overall nebulization. Without wishing to be bound by theory, by varying the distance D644, it was observed that under the test conditions, a distance of 20mm seemed to give the greatest amount of fog generated at the exit of the device. Furthermore, the single-phase simulation of the air flow in an identical configuration shows a maximization of the homogeneity of the air flow in the diffusion duct. This allows us to conclude that it is advantageous to play on the geometric parameters to homogenize the air flow in the duct, in order to minimize turbulence and thus promote the extraction of the droplets generated.
    The invention is not limited to the examples described above.
    In the various embodiments of FIGS. 1 to 18, the diffusion branches are combined with ventilation means, which notably include return means. However, it can be provided that these oblique branches can be combined with different ventilation means, of any suitable type. In this regard, these ventilation means, not shown, can be those described in the prior art, in particular in FR 3 023 735.
    Furthermore, according to a particularly advantageous variant, the device according to the invention can be devoid of such ventilation means. Indeed, as explained above, the reduction of the shocks undergone by the fine drops against the walls preserves their kinetic energy, along the path of these drops towards the exit of the diffusion branches.
    As an additional variant, not illustrated, it can be provided that the droplets of liquid, diffused in the target environment, contain an additive of any desired type, for the purposes of disinfection, deodorization or the like. In this spirit, providing an additive based on essential oil is advantageous.
    It is also possible to provide the device according to the invention with a means ensuring the disinfection of the liquid contained in the enclosure. Such a disinfection means can be of any suitable type, in particular by thermal shock (heating resistance) or else based on UV LEDs (Light Emitting Diodes Ultraviolet).
    More generally, the invention finds its application to droplet generation devices, which are of a different type from that described in the figures, namely different from a nebulization device. This droplet generation device can, among other things, be of the membrane generator type or of the acoustic fountain generator type.
    权利要求:
    Claims (13)
    [1" id="c-fr-0001]
    1. Device for generating droplets from a liquid (I; II; III; IV; V; VI; VII) comprising:
    a hollow body (1; 101; 201; 301; 401; 501; 601) delimiting a generation enclosure, means (20, 22; 120; 220; 320; 420; 520; 620) for generating droplets from a jet of liquid (J) flowing inside said enclosure, means (8; 108; 208; 308; 408; 508; 685) for evacuating a major part of the jet of liquid,
    - as well as means (6, 7; 106, 107; 206, 207; 306, 307; 406, 407; 506, 507) for diffusing droplets of a mist, formed from said jet, said generation device being characterized in that the generation enclosure comprises an upstream chamber (5; 105; 205; 305; 405; 505), known as the common chamber, intended for the flow of both liquid and mist droplets, this chamber s extending axially with reference to the enclosure, the diffusion means comprise at least one diffusion branch (6, 7; 106, 107; 206, 207; 306, 307; 406, 407; 506, 507), each branch s 'extending obliquely from the chamber, both radially outwards from this chamber and axially downstream, when viewed from above.
    [2" id="c-fr-0002]
    2. Device according to claim 1, characterized in that this device is an acoustic fountain generator.
    [3" id="c-fr-0003]
    3. Device according to claim 1 or 2, characterized in that this device is a nebulization device (I; II; III; IV; V; VI; VII), in which the generation means comprise a nebulization nozzle (20 ; 120; 220;
    320; 420; 520; 620) provided with at least one liquid inlet orifice (23; 623) and at least one liquid outlet orifice (21; 621), said nozzle being capable of generating a jet of liquid (J) at inside said nebulization enclosure, and a piezoelectric element (22), provided opposite said outlet orifice of said nozzle, capable of emitting acoustic waves in said liquid, the common chamber extends axially to from said nozzle.
    [4" id="c-fr-0004]
    4. Device according to one of the preceding claims, characterized in that, in plan view, the so-called characteristic angle (a6, a7), formed by the main axis (A1) of the hollow body (1) and the characteristic axis (A6, A7) of a respective branch, is between 5 and 60 °, in particular between 10 and 40 °, in particular close to 30 °.
    [5" id="c-fr-0005]
    5. Device according to one of the preceding claims, characterized in that the length (L5) of the common chamber (5) is between 50 and 300 millimeters, in particular between 100 and 200 millimeters, in particular close to 150 millimeters.
    [6" id="c-fr-0006]
    6. Device according to one of the preceding claims, characterized in that the longitudinal inlet section (S64, S74) of each branch is equal to a fraction of the length (L5) of the common chamber (5), said fraction being between 75 and 100%, being in particular between 85 and 90%.
    [7" id="c-fr-0007]
    7. Device according to one of the preceding claims, characterized in that several branches are provided, in particular an even number of branches, which are angularly distributed regularly around the chamber.
    [8" id="c-fr-0008]
    8. Device according to one of the preceding claims, characterized in that the evacuation means (8; 108; 208; 308; 408; 508; 685) extend said common chamber downstream, beyond the junction between the broadcasting branch and the common room.
    [9" id="c-fr-0009]
    9. Device according to claim 8, characterized in that the evacuation means comprise an axial evacuation tube (8; 108; 208; 308; 408; 508), extending said common chamber downstream, beyond of the junction between the diffusion branch and the common room.
    [10" id="c-fr-0010]
    10. Device according to claim 9, characterized in that the discharge tube (8) is extended, opposite the nozzle (20), by a downstream discharge nozzle (85) of decreasing section towards the downstream, this downstream discharge nozzle defining a downstream orifice (86) for discharging liquid.
    [11" id="c-fr-0011]
    11. Device according to one of the preceding claims, characterized in that the body (1) comprises at least one upstream liquid discharge nipple (45; 645), defining an orifice (45 '; 645') upstream of liquid discharge.
    [12" id="c-fr-0012]
    12. Device according to one of the preceding claims, characterized in that it does not have ventilation means.
    [13" id="c-fr-0013]
    13. Method of implementing a device according to one of the preceding claims,
    5 in which:
    liquid is admitted into the enclosure, said liquid is made to flow into the common chamber, and a mist of droplets formed from said liquid, a majority of droplets are made to flow in each branch of diffusion 10 said fine, the size of which is less than a predetermined value, a fraction of the liquid which is not transformed into droplets and, possibly, so-called large droplets, the size of which is greater than said predetermined value, is discharged by the evacuation means.
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    同族专利:
    公开号 | 公开日
    FR3070879B1|2020-06-05|
    WO2019048761A1|2019-03-14|
    EP3681644A1|2020-07-22|
    EP3681644B1|2021-08-25|
    引用文献:
    公开号 | 申请日 | 公开日 | 申请人 | 专利标题
    JPH01317825A|1988-06-18|1989-12-22|Diesel Kiki Co Ltd|Deodorizing device for car air conditioner|
    US20160067368A1|2013-04-30|2016-03-10|Areco Finances Et Technologie - Arfitec|Nebulizer system for freshening the air|
    FR3023735A1|2014-07-17|2016-01-22|Areco Finances Et Technologie Arfitec|COMPACT NEBULIZER FOR AIR REFRIGERATION|
    FR3054808A1|2016-08-04|2018-02-09|Valeo Systemes Thermiques|NEBULATION SYSTEM FOR MOTOR VEHICLE|
    FR2721839B1|1994-07-04|1996-10-25|Imra Europe Sa|SPRAYING DEVICE, ESPECIALLY WATER IN THE FORM OF MICRO-DROPLETS, CAPABLE OF OPERATING IN A NON-STATIONARY MEDIUM|
    FR2743313B1|1996-01-04|1998-02-06|Imra Europe Sa|HIGH-YIELD SPRAYING DEVICE, ESPECIALLY MICRO-DROPLET WATER|FR3095604A1|2019-04-30|2020-11-06|Areco Finances Et Technologie - Arfitec|Device for generating droplets from a liquid, comprising means for sterilizing this liquid|
    WO2021152261A1|2020-01-29|2021-08-05|Valeo Systemes Thermiques|Nebuliser system for a motor vehicle|
    FR3106509B1|2020-01-29|2022-02-18|Valeo Systemes Thermiques|NEBULIZING SYSTEM FOR MOTOR VEHICLE|
    法律状态:
    2019-03-15| PLSC| Search report ready|Effective date: 20190315 |
    2019-09-20| PLFP| Fee payment|Year of fee payment: 3 |
    2020-09-17| PLFP| Fee payment|Year of fee payment: 4 |
    2021-09-14| PLFP| Fee payment|Year of fee payment: 5 |
    优先权:
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    EP18773801.8A| EP3681644B1|2017-09-11|2018-09-03|Device for generating droplets from a liquid comprising improved means for diffusion of the mist, and method for implementing same|
    PCT/FR2018/052143| WO2019048761A1|2017-09-11|2018-09-03|Device for generating droplets from a liquid comprising improved means for diffusion of the mist, and method for implementing same|
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