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    • 专利摘要:
    The invention relates to a method for ventilating a dynamic air duct (25) of a vehicle, in particular an aircraft, comprising at least one heat exchanger (20). The dynamic air channel is equipped with an injection horn (29) comprising a plurality of compressed air inlets (34, 38) connected to a plurality of separate sources (13, 17) of compressed air of vehicle, and a plurality of compressed air outlet nozzles (44, 48). At least two nozzles are independently connected to at least two separate sources of compressed air of the vehicle.
    公开号:FR3063042A1
    申请号:FR1751443
    申请日:2017-02-23
    公开日:2018-08-24
    发明作者:Cecile Bombled;Frederic SANCHEZ
    申请人:Liebherr Aerospace Toulouse SAS;
    IPC主号:
    专利说明:

    Holder (s): LIEBHERR-AEROSPACE TOULOUSE SAS.
    Extension request (s)
    Agent (s): CABINET BARRE LAFORGUE & ASSOCIES.
    METHOD FOR VENTILATION OF A DYNAMIC AIR CHANNEL AND DEVICE FOR ENVIRONMENTAL CONTROL AND VEHICLE IMPLEMENTING THIS METHOD.
    FR 3 063 042 - A1 (bj) The invention relates to a method for ventilating a dynamic air channel (25) of a vehicle - in particular an aircraft - comprising at least one heat exchanger (20). The dynamic air channel is fitted with an injection tube (29) comprising a plurality of compressed air inlets (34, 38) connected to a plurality of sources (13, 17) distinct from the compressed air of the vehicle, and a plurality of compressed air outlet nozzles (44, 48). At least two nozzles are independently connected to at least two separate sources of compressed air from the vehicle.

    VENTILATION METHOD FOR A DYNAMIC AIR CHANNEL AND ENVIRONMENTAL CONTROL DEVICE AND VEHICLE
    IMPLEMENTING THIS PROCESS
    The invention relates to a method of ventilating a dynamic air channel 5 of a vehicle, and in particular of an aircraft. It extends to an environmental control device of at least one vehicle cabin, in particular an aircraft, in which such a ventilation process is implemented. It also extends to a vehicle, in particular an aircraft, equipped with an environmental control device according to the invention.
    Throughout the text, the term "cabin" designates any interior space of a vehicle, in particular an aircraft, in which the air pressure and / or temperature must be controlled. It can therefore be either a passenger cabin, a cockpit, a hold, a cargo loading space, etc. The expression “environmental control” designates the fact of controlling the temperature and / or the pressure and / or the humidity and / or the composition (quality) of the air in a cabin.
    In addition, the expression “compressed air source” designates any device capable of generating an air flow at a pressure greater than the ambient static pressure (that is to say the atmospheric pressure), independently of the movement of the vehicle. . In particular, the term "compressor" designates any device capable of converting mechanical energy into pneumatic energy, that is to say into compressed air; this term therefore designates in particular both a machine (in particular a rotary machine with radial or axial circulation, or a piston machine (s)) delivering compressed air, as well as a part of machine, for example a compression stage or a compression wheel, of a machine delivering compressed air. For example, several stages or compression wheels of the same machine delivering compressed air constitute several sources of compressed air.
    Vehicle cabins are most often fitted with at least one environmental control device. Vehicles traveling at relatively high speed such as aircraft or high-speed trains are provided with at least one dynamic air channel making it possible to receive air at dynamic pressure under the effect of the movement of the vehicle, and to supply at least one heat exchanger placed in the dynamic air channel, and associated with an environmental control device. Such a heat exchanger can for example be an intermediate exchanger (that is to say interposed between the compressor and the turbine) of an air cycle cooling turbocharger (with or without an electric drive motor ); a cooling exchanger between several compressors - in particular between a first compressor with an electric motor and a compressor of an air cycle cooling turbocharger - (with or without an electric drive motor); an air pre-cooling exchanger taken from a turbojet compressor; any other heat exchanger for cooling a fluid other than air (refrigerant, fuel, ...) ...
    The general problem which arises with such devices is that of the ventilation of such a dynamic air channel when the vehicle speed is insufficient, in particular when it is stationary, or, in the case of a aircraft, taxiing. In fact, the requirements for cooling the cabin air can be significant under these conditions, and therefore require optimal operation of the environmental control device, and in particular of each heat exchanger interposed in each dynamic air channel.
    US 7797962 describes in particular a method of ventilating such a dynamic air channel in which an injection pump (in English "jet pump") is placed in the dynamic air channel downstream of the exchanger , this injection tube being supplied with compressed air via regulation valves from a part of the air flow delivered by the compressor of a motorized air cycle turbocharger and / or from a flow d air supplied by a second source of compressed air such as a second motorized compressor or bleed air from a compressor of a turbojet engine of the aircraft.
    With such a method and such a device, the injection tube must be able to operate with one and / or the other of the compressed air sources, including in transient regimes when one or the other of these sources. compressed air is interrupted or malfunctions. The injection tube must therefore be able to operate under a wide range of pressures and flow rates. However, if such an injection tube can be optimized for an operating point, its performance generally degrades significantly when the pressure and / or flow at the inlet varies (nt) relative to this operating point . It should also be noted in this respect that the injection tube of a dynamic air channel must also be particularly small in order not to hinder the circulation of the air flow in the channel, and of mass as low as possible so as not to burden the weight of the vehicle. These constraints increase all the more the problem of optimizing the operating point, which is all the more delicate since the injection tube is of reduced size and / or mass. In addition, degraded operation of the injection tube causes not only insufficient ventilation of the dynamic air channel, but also a very significant noise which can be a considerable discomfort in the environment of the vehicle or for the passengers of the vehicle, especially in the case of an airliner or a train.
    In addition, when several rotary compressors are connected to the same injection tube, there is a risk that a malfunction (such as pumping) of one compressor will inadvertently affect the operation of another compressor via the tube injection. To avoid this, it is necessary to provide specific provisions for controlling the injection valve supply valves, which complicates the system.
    The invention therefore aims generally to overcome these drawbacks by proposing a method of ventilating a dynamic air channel by which each injection tube can be supplied from one and / or the other of a plurality of sources of compressed air from the vehicle while having optimal operation - in particular with improved ventilation performance and a reduction in acoustic noise generated by the injection tube - over a wide range of inlet pressures and flow rates entry.
    The invention also aims to obtain these results with a reduced mass and size, compatible with the constraints of integrating the injection tube into a dynamic air channel.
    The invention also aims to simplify the management of the supply of each injection tube of a dynamic air channel from different sources of compressed air, while avoiding any untimely interference from several sources of compressed air. between them via an injection tube, in particular when at least one of these compressed air sources is a rotary compressor.
    The invention also aims to propose a device for environmental control of a vehicle cabin, in particular an aircraft, having the same advantages.
    The invention therefore relates to a method of ventilating a dynamic air channel of a vehicle, in particular an aircraft, said dynamic air channel comprising:
    - a dynamic air inlet capable of receiving a flow of air at dynamic pressure under the effect of a movement of the vehicle,
    - At least one heat exchanger arranged to be able to receive at least part of said dynamic air flow, process in which the dynamic air channel is equipped with at least one injection pump arranged to be able to be supplied with compressed air delivered by compressed air sources from the vehicle, characterized in that the dynamic air channel is equipped with at least one injection tube, called a multiple injection tube:
    - comprising a plurality of compressed air inlets and a plurality of compressed air outlet nozzles, each nozzle being connected to at least one of said compressed air inlets,
    - of which said compressed air inlets are connected to a plurality of (separate) sources of compressed air from the vehicle,
    - a first nozzle of which is connected to at least one first compressed air inlet connected to at least one first source of compressed air from the vehicle, this first nozzle being able to receive compressed air supplied by at least one such first source of vehicle compressed air,
    of which at least one nozzle, called the second nozzle, distinct from the said first nozzle, is:
    o isolated from each first compressed air inlet, o connected to at least one inlet, called the second compressed air inlet:
    separate from each first compressed air inlet, and connected to at least one source of compressed air from the vehicle, known as the second compressed air source, separate from each first source of compressed air, each second nozzle being able to receive compressed air supplied by at least one such second source of compressed air, without being able to receive compressed air supplied by any first source of compressed air (that is to say by any source of compressed air connected to a first compressed air inlet connected to said first nozzle).
    The invention extends to an environmental control device for at least one vehicle cabin, in particular an aircraft cabin, in which a method according to the invention for ventilating at least one dynamic air channel is implemented. The invention therefore extends to an environmental control device for at least one vehicle cabin, in particular an aircraft, comprising:
    - a plurality of compressed air sources,
    - at least one dynamic air channel comprising:
    o a dynamic air inlet capable of receiving a flow of air at dynamic pressure under the effect of a movement of the vehicle, o at least one heat exchanger arranged to be able to receive at least part of said dynamic air flow , o at least one injection tube arranged to be able to be supplied with compressed air supplied by at least part of said compressed air sources, characterized in that at least one dynamic air channel comprises at least one injection, called multiple injection tube:
    - comprising a plurality of compressed air inlets and a plurality of compressed air outlet nozzles, each nozzle being connected to at least one of said compressed air inlets,
    - whose said compressed air inlets are connected to a plurality of said compressed air sources,
    - a first nozzle of which is connected to at least one first compressed air inlet connected to at least one first source of compressed air, this first nozzle being able to receive compressed air supplied by at least one such first source of air compressed,
    of which at least one nozzle, called the second nozzle, distinct from the said first nozzle, is:
    o isolated from each first compressed air inlet, o connected to at least one inlet, called the second compressed air inlet:
    distinct from each first compressed air inlet, and connected to at least one source of compressed air, called the second compressed air source, distinct from each first compressed air source, each second nozzle being able to receive compressed air delivered by at least one such second source of compressed air, without being able to receive compressed air delivered by any first source of compressed air (that is to say by any source of compressed air connected to a first inlet compressed air connected to said first nozzle).
    The invention also extends to a method of ventilating a dynamic air channel implemented in a device according to the invention for environmental control of at least one vehicle cabin - in particular an aircraft -.
    In particular, in a method and a device according to the invention, a first compressed air inlet of the same multiple injection tube is connected to at least one first source of compressed air from the vehicle in order to be able to receive compressed air supplied by at least one such source of compressed air from the vehicle; and a second compressed air inlet of this same multiple injection tube, distinct from said first compressed air inlet, is connected to at least one second source of compressed air from the vehicle, distinct from each first air source compressed vehicle, to be able to receive compressed air supplied by at least one such second source of compressed air from the vehicle. Each nozzle connected to such a second compressed air inlet is not connected to said first compressed air inlet.
    Whereas the fact of independently supplying several different nozzles, and in particular several different compressed air inlets, from the same multiple injection horn of a dynamic air channel could be considered at first sight as penalizing -in particular the fact that such a supply requires several separate lines to independently connect each compressed air inlet of the multiple injection pipe to at least one of the compressed air sources of the vehicle, the inventors have found, on the contrary, that the use of a multiple injection tube with several inputs and several independent output nozzles independently connected to separate compressed air sources actually allows a considerable gain both on the aerodynamic and acoustic performance of the tube, as on the mass and overall dimensions of the device, and also a significant simplification of the management of the various sources of compressed air, in particular in the case of c rotary compressors capable of pumping.
    The same dynamic air channel is equipped with at least one multiple injection tube, but may comprise several injection tubes, for example a multiple injection tube or several multiple injection tubes; a single injection tube (i.e. with a single nozzle) or multiple single injection tubes. However, in certain preferred embodiments according to the invention, the same dynamic air channel is equipped with one and only one injection tube, which is a multiple injection tube according to the invention.
    Preferably, in the same dynamic air channel, at least one multiple injection tube according to the invention is arranged downstream of at least one - in particular of each - heat exchanger of the dynamic air channel. Indeed, in general, each heat exchanger of such a dynamic air channel is used for cooling a fluid (in particular air intended for at least one cabin) from pressurized air dynamic flowing in the dynamic air channel. It is therefore preferable that the compressed air injected into the dynamic air channel by such an injection tube, which is at relatively high temperature, is only done downstream of such a cooling exchanger. However, there is nothing to prevent the provision, in certain applications, of at least one injection tube, including a multiple injection tube, upstream of at least one exchanger of the dynamic air channel.
    Likewise, an environmental control device according to the invention can comprise several dynamic air channels. However, in certain preferred embodiments according to the invention, the environmental control device according to the invention comprises a single dynamic air channel.
    In a method and a device according to the invention, each second nozzle being distinct from said first nozzle, is not connected to each first compressed air inlet, that is to say to each connected compressed air inlet to this first nozzle. Thus, each second nozzle can be supplied with compressed air from at least one second source of compressed air which is not a first source of compressed air supplying said first nozzle. This condition implies a pneumatic supply separation of at least two separate nozzles from at least two separate compressed air sources, but does not prevent the provision of at least one nozzle - or even that each nozzle - d 'A multiple injection tube is arranged to be able to receive compressed air from several sources of compressed air in the vehicle. Thus, for example, said first nozzle can be connected to several first separate sources of compressed air. Likewise, each second nozzle can be connected to several separate second compressed air sources, none of them constituting a first compressed air source (connected to said first nozzle). However, in certain advantageous embodiments of the invention, each nozzle of at least one multiple injection tube - in particular of each multiple injection tube - is connected to a single source of compressed air, this is that is, can receive compressed air from only one and only one source of compressed air.
    The invention applies with sources of compressed air available on board the vehicle which can be of any kind (extraction of compressed air from a compression stage of a turbojet engine, rotary compressor of a turbocharger with or without '' an electric motor, pressurized cabin, air flow for ventilation or cooling of vehicle components ...). Each of the compressed air sources is capable of delivering compressed air independently of the movement of the vehicle, that is to say including when the vehicle is traveling at low speed or is stopped.
    In certain advantageous embodiments in accordance with the invention at least one - in particular each - of said compressed air sources connected to the same multiple injection pipe of a dynamic air channel is a compressor - in particular a compressor rotary, in particular a rotary compressor driven at least by an electric motor (only by such an electric motor and / or possibly by another drive device such as a turbine) - an environmental control device of at least a vehicle cabin. In particular, advantageously and according to the invention, at least one of said first and second sources of compressed air is a rotary compressor of an environmental control device of at least one cabin of the vehicle. Thus, at least one rotary compressor d’ of an environmental control device of at least one cabin of the vehicle is connected to at least one inlet of a multiple injection tube.
    In these embodiments, advantageously and according to the invention, each nozzle of the same injection tube - in particular of the same multiple injection tube - of a dynamic air channel is connected to at most one compressor rotary. Thus, if a nozzle is connected to a rotary compressor and to another source of compressed air, this other source of compressed air is not a rotary compressor of the vehicle. More particularly, advantageously and according to the invention, the same nozzle of an injection tube -in particular of an injection tube multiplied with a rotary compressor of the vehicle is connected only to this rotary compressor, to the exclusion of all other source of compressed air from the vehicle. Thus, if the vehicle comprises several rotary compressors, two rotary compressors distinct from the vehicle are not connected to the same nozzle of the same injection tube - in particular to the same nozzle of the same multiple injection tube -. In this way, any coupling and any interference between two rotary compressors is avoided via a nozzle of an injection tube, in particular in the event of pumping of a rotary compressor.
    Conversely, there is nothing to prevent providing at least one - in particular that each - source of compressed air from the vehicle is connected to several nozzles of the same multiple injection tube. For example, a second source of compressed air from the vehicle can be connected to several second nozzles of the same multiple injection tube. In particular, the same rotary compressor - in particular the same rotary compressor driven by an electric motor - of the vehicle can be connected to several nozzles of the same multiple injection tube.
    Also, there is nothing to prevent the provision of at least one nozzle - or that each nozzle - of a multiple injection tube is connected to several compressed air inlets separate from the multiple injection tube. Thus, for example, the first nozzle can be connected to several first separate compressed air inlets. Similarly, the second nozzle can be connected to several second separate compressed air inlets, none of them constituting a first compressed air inlet, that is to say being connected to the first nozzle. However, in certain advantageous embodiments of the invention, each nozzle of at least one multiple injection tube - in particular of each multiple injection tube - is connected to a single compressed air inlet of this tube. 'multiple injection, that is to say can receive compressed air from only one and only one compressed air inlet.
    Furthermore, nothing prevents the provision of at least one, in particular that each compressed air inlet of at least one, in particular of each multiple injection pipe, is connected to several sources of compressed air in the vehicle. .
    However, in certain advantageous embodiments of the invention, each compressed air inlet of at least one, in particular of each multiple injection pump, is connected to at most one rotary compressor of the vehicle. Thus, if a compressed air inlet is connected to a rotary compressor and another source of compressed air, this other source of compressed air is not a rotary compressor. More particularly, advantageously and according to the invention, any inlet of compressed air from an injection tube - in particular from an injection tube multiplied by a rotary compressor of the vehicle is connected only to this rotary compressor, to the exclusion of any other source of compressed air from the vehicle. Thus, if the vehicle comprises several rotary compressors, two rotary compressors distinct from the vehicle are not connected to the same compressed air inlet of the same injection tube - in particular to the same nozzle of the same injection tube multiple-. In this way, any coupling and any interference between two rotary compressors is avoided via a compressed air inlet of an injection tube, in particular in the event of pumping of a rotary compressor.
    In certain particular embodiments of the invention, each compressed air inlet of at least one, in particular each of the multiple injection tubes, is connected to a single source of compressed air, in particular to a single rotary compressor. vehicle, each compressed air inlet and each nozzle of this multiple injection tube can only receive compressed air delivered by a single source of compressed air - in particular by a single rotary compressor - from the vehicle.
    Furthermore, nothing prevents reciprocally providing that at least one same source of compressed air from the vehicle is connected to several compressed air inlets of the same multiple injection tube, or of several injection tubes ( multiple or single) of the same dynamic air channel, or of several dynamic air channels of the vehicle. In particular, several compressed air inlets from the same multiple injection tube can be connected to the same compressed air source in the vehicle.
    However, in certain advantageous embodiments of the invention, each source of compressed air from the vehicle connected to at least one multiple injection tube of at least one - in particular of each - dynamic air channel is connected to a single compressed air inlet from this multiple injection tube. In other words, each source of compressed air in the vehicle is connected to a single compressed air inlet of each multiple injection tube that it supplies with compressed air. And the different compressed air inlets of the same multiple injection pipe are connected independently of each other to different compressed air sources of the vehicle, each compressed air inlet being connected to a compressed air source of the its own vehicle, two separate compressed air inlets from the same multiple injection tube being connected to two separate compressed sources of the vehicle, respectively.
    Preferably, for the same dynamic air channel, each source of compressed air - in particular each rotary compressor - of the vehicle is connected to a single injection tube - in particular to a single compressed air inlet of a single tube multiple injection of this dynamic air channel.
    In a method and a device according to the invention, the same compressed air inlet of a multiple injection tube can be connected to a single nozzle of this multiple injection tube, or on the contrary to several nozzles of this tube multiple injection.
    The invention applies in particular advantageously to an aircraft comprising an environmental control device provided with several rotary compressors each driven at least by an electric motor. In this particular application, advantageously and according to the invention, the compressed air inlets of the same multiple injection horn of the same dynamic air channel are connected to a plurality of such separate rotary compressors, each inlet of compressed air from the tube being connected only to a single rotary compressor in order to be able to receive only compressed air supplied by this rotary compressor. In particular, the invention makes it possible to offload one and / or the other of the rotary compressors from an environmental control device of at least one aircraft cabin, and for example to avoid pumping of a compressor. rotary. In addition, if a rotary compressor is pumped, there is no risk that this pumping will cause a malfunction of another source of compressed air, in particular another compressor.
    In addition, a multiple injection tube of a device according to the invention can be the subject of various structural variants. In certain advantageous embodiments and in accordance with the invention, the injection tube has at least a first central nozzle connected to a first compressed air inlet and at least a series of nozzles, called second peripheral nozzles, connected to a second compressed air inlet and extending around each first central nozzle.
    Thus, the different nozzles can advantageously be arranged so as to deliver compressed air in the same general direction of injection, and in particular by being arranged in concentric circles, a plurality of nozzles arranged in the same circle being connected to a same entry of compressed air from the tube. Such an arrangement facilitates the mixing of the different compressed air flows when the different compressed air inlets are supplied, and standardizes the behavior of the injection tube whatever it is and / or the other of the compressed air inlets which are (are) supplied. This results in aerodynamic and acoustic performance of the injection tube which can then be optimized.
    In certain advantageous embodiments of a method and a device according to the invention, a multiple injection tube comprises a number of outlet nozzles between three and eight, in particular advantageously a first central outlet nozzle and three with six second peripheral nozzles. In a preferred embodiment, a multiple injection tube includes four second peripheral nozzles.
    Furthermore, in certain advantageous embodiments of the invention, the injection tube comprises:
    - an outlet plenum arranged to be able to receive the compressed air delivered by each nozzle,
    - an air inlet, called low pressure air inlet, arranged to receive air from the dynamic air inlet of the dynamic air channel and to circulate it in said plenum,
    - Said nozzles and said low pressure air inlet being arranged so that the compressed air from any one of the nozzles can mix in said plenum with the air supplied by said low pressure air inlet by forming a mixture air flow causing ventilation of the dynamic air channel. Preferably, said low pressure air inlet and the plenum are interposed in series in the dynamic air channel, the low pressure air inlet receiving the entire air flow passing through the air channel dynamic.
    In addition, the arrangement of the low pressure air inlet into the injection tube can be the subject of different alternative embodiments. Thus, nothing prevents the provision that the low pressure air inlet is an axial air inlet, coaxial with the compressed air outlet nozzles. However, in certain advantageous embodiments, said low pressure air inlet is a radial air inlet to the nozzles of the injection tube. Such a low-pressure radial air inlet delivers low-pressure air into the plenum in a radial direction from the outside to the inside relative to the general direction of injection defined by the nozzles.
    Also in certain advantageous embodiments, said plenum is in the form of a Venturi tube, that is to say has a neck (zone of smallest section of the plenum, considered independently of the nozzles), the nozzles are arranged to be able to deliver compressed air at the neck or upstream of the neck, and said low pressure air inlet is arranged to supply the plenum upstream of the neck. The section of the plenum upstream of the cervix is preferably greater than that of the cervix, that is to say constitutes a convergent section up to the cervix. The plenum section downstream of the neck is preferably also greater than that of the neck and constitutes a divergent section from the neck.
    Furthermore, in certain advantageous embodiments in accordance with the invention, the dynamic air channel is provided with a pipe for bypassing the injection tube, this bypass pipe connecting an area of the dynamic air channel to the upstream of said low pressure air inlet of the injection tube to said plenum. In addition, advantageously and according to the invention, said bypass pipe is provided with a valve suitable for:
    - allow air circulation in the bypass line when none of the compressed air inlets of the injection tube is supplied with compressed air,
    - allow air circulation in the low pressure air inlet of the injection tube when at least one of the compressed air inlets of the injection tube is supplied with compressed air. Thus, the injection tube does not obstruct the dynamic air circulation in the dynamic air channel when the vehicle is moving at sufficient speed, but allows appropriate ventilation of the dynamic air channel when the injection tube is supplied with compressed air, the vehicle not being traveling at sufficient speed.
    In general, a dynamic air channel of a vehicle also has an air outlet to the atmosphere outside the vehicle after passing through the dynamic air channel. Consequently, advantageously and according to the invention, said nozzles of the injection tube deliver compressed air in the direction of such an air outlet from the dynamic air channel into the atmosphere outside the vehicle. Likewise, said plenum communicates with an air outlet from the dynamic air channel to the atmosphere outside the vehicle, or forms such an air outlet from the dynamic air channel. The invention however also applies in embodiments where the dynamic air channel has an air outlet which does not communicate with the atmosphere outside the vehicle.
    The invention thus makes it possible to ventilate a dynamic air channel, that is to say to generate an air flow in the dynamic air channel independently of the movement of the vehicle, redundantly by several air sources compressed. It is thus possible in particular to relieve one and / or the other source of compressed air as necessary while maintaining the ventilation function of the dynamic air channel. The invention also makes it possible to optimize the aerodynamic and acoustic performance of the injection tube, this injection tube being able to be adapted and optimized for the various sources of compressed air in the vehicle. In particular, each compressed air inlet and each outlet nozzle can be specifically adapted and optimized to the characteristics of the compressed air supplied by the compressed air source to which this compressed air inlet is connected. In addition, compared to a simple injection tube, for the same ventilation effect, the injection pressure at the outlet of the nozzles can be reduced, and the air circulation in the dynamic air channel is improved. The aerodynamic performance of the multiple injection tube can be fully maintained in the event of a malfunction of one of the compressed air sources, for example in the event of pumping of a rotary compressor, by supplying the multiple injection tube with from another source of compressed air.
    The invention extends to a vehicle - in particular to an aircraft characterized in that it comprises at least one environmental control device according to the invention and / or in which a ventilation method according to the invention of at least one channel dynamic air is used.
    The invention also relates to a ventilation method, an environmental control device for at least one vehicle cabin, in particular an aircraft, and a vehicle, in particular an aircraft, characterized in combination by all or some of the characteristics mentioned above. above or below.
    Other objects, characteristics and advantages of the invention will appear on reading the following description given without limitation and which refers to the appended figures in which:
    - Figure 1 is a general diagram of an exemplary aircraft environmental control device according to an embodiment of the invention, in which a ventilation method according to the invention of a dynamic air channel is put implemented,
    - Figures 2 and 3 are schematic perspective views, and, respectively in axial section, illustrating an exemplary embodiment of the nozzles of an injection tube of an environmental control device according to the invention implementing a method ventilation according to the invention,
    - Figure 4 is a schematic elevational view of an exemplary embodiment of an outlet section of a dynamic air channel of an environmental control device according to the invention comprising an injection tube for setting implementing a ventilation method according to the invention,
    FIG. 5 is a schematic view in axial section along the line V-V in FIG. 4.
    FIG. 1 represents an example of an environmental control device according to the invention of an aircraft cabin 11. This environmental control device is of the air cycle type, and includes:
    a machine 12 with a motorized air cycle comprising a first rotary compressor 13 driven by a shaft 14 on which are coupled a turbine 15 and an electric motor 16,
    - a second rotary compressor 17 motorized by a motor 19 coupled to 5 the shaft 18 of the compressor,
    - An intermediate exchanger 20, a first circuit (hot pass) of which is interposed between the outputs of the compressors 13, 17 and the inlet of the turbine 15, by means of a loop 21 for extracting water. This intermediate exchanger 20 makes it possible to cool the compressed air delivered by each compressor 13, 17 before introducing it into the water extraction loop 21 and into the turbine 15.
    The compressors 13, 17 are supplied with air coming from an air intake port 43 or scoop capturing the air outside the aircraft. The outlets of the two compressors 13, 17 deliver compressed air through outlet pipes 33, respectively 37, which meet at a node 22 connected by a pipe 23 to the first circuit of the intermediate exchanger 20.
    The intermediate exchanger 20 is interposed in a dynamic air channel 25 having a dynamic air inlet 24 capable of receiving a flow of air at dynamic pressure under the effect of the movement of the aircraft and, opposite from this dynamic air inlet 24, a dynamic air outlet 26 rejecting the air having passed through the dynamic air channel 25 into the atmosphere. The dynamic air inlet 24 is equipped with a valve 27 allowing the section of this air inlet 24 to be adjusted. The water extracted in the water extraction loop 21 is advantageously injected into the dynamic air channel 25 by an injector 28 upstream of the intermediate exchanger 20, to increase the cooling capacity. The air circulating in the dynamic air channel 25 passes through a second circuit (cold pass) of the intermediate exchanger 20.
    A multiple injection pipe 29 is placed in the dynamic air channel 25 downstream of the intermediate exchanger 20 to ventilate the dynamic air channel 25 when the aircraft is on the ground. This multiple injection pipe 29 has, in the example shown, two compressed air inlets 34, 38. The first compressed air inlet 34 is connected to the outlet pipe 33 of the first compressor 13 via a pipe 35 via a first valve 36 for supplying the injection nozzle 29. The second compressed air inlet 38 is connected to the outlet pipe 37 of the second compressor 17 via a pipe 39 via a second valve 40 for supplying the injection nozzle 29. The injection pipe 29 is thus connected in parallel to several pipes 35, 39 for supplying compressed air.
    Consequently, when the first valve 36 is open, the first inlet 34 of the injection pipe 29 is supplied with compressed air from the first compressor 13. Similarly, when the second valve 40 is open, the second inlet 38 of the injection pipe 29 is supplied with compressed air from the second compressor 17. These two valves 36, 40 for supplying the injection pipe 29 are valves controlled independently and can be controlled independently of one of the another by a control unit of the environmental control device according to the invention.
    The injection pipe 29 also includes an inlet, called low pressure inlet 32, receiving the air circulating in the dynamic air channel 25 upstream of the injection pipe 29, that is to say downstream of the intermediate exchanger 20.
    The first inlet 34 of the injection pipe 29 supplies at least one first outlet nozzle 44 of the injection pipe 29 injecting compressed air into the dynamic air channel 25 downstream of the injection nozzle 29, that is to say towards the outlet 26 of the dynamic air channel 25. Consequently, each first nozzle 44 can be adapted and optimized to the pressure and flow rate of the compressed air delivered by the first compressor 13, to allow ventilation of the dynamic air channel 25, and therefore in particular the operation of the 'intermediate exchanger 20, when the aircraft is on the ground.
    The second inlet 38 of the injection pipe 29 makes it possible to supply at least a second outlet nozzle 48 of the injection pipe 29 injecting compressed air into the dynamic air channel 25 downstream of the injection nozzle 29, that is to say towards the outlet 26 of the dynamic air channel 25. Consequently, each second nozzle 48 can be adapted and optimized to the pressure and the flow rate of compressed air delivered by the second compressor 17, to allow ventilation of the dynamic air channel 25, and therefore in particular the operation of the intermediate exchanger 20, when the aircraft is on the ground.
    Thus, the multiple injection pipe 29 can be supplied either only from the first compressor 13, or only from the second compressor 17, or from the two compressors 13, 17, to ventilate the dynamic air channel 25 when the aircraft is on the ground. In all the conditions of supply of the injection tube 29, the latter exhibits optimum operation, each of the outlet nozzles being optimized for the air it receives. In addition, the dynamic air channel 25 can still be ventilated, even in the event of the failure or interruption of one or other of the compressors 13, 17, for example in the event of pumping of one of the compressors 13, 17. It is also possible to precisely modulate the operation of each compressor 13, 17 to avoid any pumping phenomenon, while preserving the ventilation function of the dynamic air channel by the multiple injection horn 29. And, in the event of pumping of a compressor 13, 17, this pumping phenomenon has in any event no repercussions on the other compressor, the multiple injection pipe 29 isolating the two compressors 13, 17 one the other.
    In the embodiment shown in Figures 2 to 5, the injection tube includes a mounting flange 30 at the entrance to a plenum 31, a first central nozzle 44 injecting compressed air in an injection direction axial orthogonal to the flange 30 towards the outlet 26 of the dynamic air channel 25, and a series of four second peripheral nozzles 48 arranged in a circle around the first nozzle 44, the second nozzles 48 injecting compressed air according to the same axial injection direction.
    The first nozzle 44 is supplied by the first compressed air inlet 34 formed by a bent tube connected on the outside to the flange 30 to the first nozzle 44. The second nozzles 48 are supplied by the second compressed air inlet 38 formed by a bent tube connected to the outside of the flange 30 by a frustoconical sleeve 41. The bent tube forming the first air inlet 34 passes radially through the frustoconical sleeve 41 to be connected to the first central nozzle 44. The frustoconical sleeve 41 is connected to the second peripheral nozzles 48 to supply them with compressed air.
    Preferably, the second nozzles 48 are all similar, of the same shape and dimensions, and have axial ends 49 situated in the same plane parallel to the flange 30, and the first central nozzle 44 has an axial end 45 placed between the second nozzles 48 , that is to say set back towards the flange 30 relative to the axial ends 49 of the second nozzles 48, the first central nozzle 44 being of shorter length than the second peripheral nozzles 48. In this way the passage of low pressure air between the second nozzles 48 is favored, for the benefit of better air mixing, in particular when the second nozzles 48 are supplied with compressed air, and that the first central nozzle 44 is not. Indeed, in normal operation, if the flow constraints in the dynamic air channel allow it, it is preferable to supply the second peripheral nozzles 48 rather than the first central nozzle 44 for ventilating the dynamic air channel, these second nozzles 48 peripherals providing better mixing and having better acoustic performance.
    The part shown in Figures 2 and 3 forming the compressed air inlets 34, 38, the mounting flange 30 and the nozzles 44, 48 for output from the injection horn 29 can in particular be produced by any manufacturing technique by addition of material, that is to say by three-dimensional printing.
    The plenum 31 extends longitudinally parallel to the direction of axial injection of the nozzles 44, 48, the flange 30 being mounted at an axial end 50 of the plenum 31. The plenum 31 has a first inlet section 51 formed by the wall 42 peripheral of the dynamic air channel 25, this first section 51 extending from the axial end 50 carrying the flange 30 and containing the nozzles 44, 48. This first section 51 receives radially, that is to say say orthogonally to the direction of axial injection, from outside to inside, the air circulating in the dynamic air channel 25 downstream of the intermediate exchanger 20, and therefore forms an inlet 32 of low pressure air from the injection tube 29. The plenum 31 has a neck 52 of minimum cross section (considered without the nozzles 44, 48), in particular reduced compared to that of the first section 51. The different nozzles 44, 48 are arranged in the first section 51 so that the compressed air delivered by these nozzles 44, 48 is directed towards the neck 52, inside the section of the latter. Advantageously, the axial ends 49 of the longest nozzles 48 are disposed immediately upstream from the neck 52. The plenum 31 has, from the neck
    52, a divergent outlet section 53 serving as a mixer and a diffuser, in which the low-pressure air coming from upstream from the dynamic air channel 25 and the compressed air supplied by the nozzles 44, 48 mixed. Plenum 31 thus forms a Venturi tube facilitating the mixing of flows and accelerating the resulting flow. The axial end of the divergent 53 of the plenum 31 forms the outlet 26 of the dynamic air channel 25.
    The outlet section 53 of the plenum 31 is also advantageously connected by a bypass pipe 54 to the dynamic air channel 25 upstream of the low pressure air inlet 32 of the injection pipe 29. This bypass line 54 is provided with a valve 55 making it possible to close the bypass line 54 when compressed air is supplied to at least one of the inlets 34, 38 of the injection pipe 29, the air coming from the exchanger 20 intermediate in the dynamic air channel 25 passing through the injection tube 29; or open the bypass line 54 when the injection tube 29 is not supplied with compressed air so that air arriving downstream of the intermediate exchanger 20 passes directly into the line 54 of bypassing towards outlet 26 of dynamic air channel 25. It should be noted that when the bypass line 54 is open, a fraction of the flow downstream of the intermediate exchanger 20 nevertheless passes through the plenum 31 of the injection tube 29.
    The tests have demonstrated that the use of a multiple horn 29 according to the invention allows, compared with a single-nozzle horn of the prior art:
    - a reduction from 10% to 20% of the injection pressure at the inlet of the tube, for the same flow generated by the tube; this results in a decrease in the acoustic level and a decrease in the energy consumed;
    - for the same flow rate at the outlet of the tube, an increase of around 20% in the mass flow rate generated in the dynamic air channel.
    The invention can be the subject of numerous variant embodiments with respect to the embodiments described above and represented in the figures. In particular, the injection pipe 29 can be provided with more than two compressed air inlets, and the outlet nozzles can be arranged in any suitable way, in successive concentric circles or not. Furthermore, in general, a single injection pipe provided with several compressed air inlets and several outlet nozzles in accordance with the invention is sufficient to ventilate the same dynamic air channel. However, nothing prevents the provision of several injection tubes each having several inlets and several outlet nozzles in accordance with the invention in the same dynamic air channel. Nothing prevents either from providing several dynamic air channels for the same environmental control device, and a ventilation method according to the invention of each of these dynamic air channels or only part of them. them. The invention also applies to the ventilation of a dynamic air channel of a vehicle other than an aircraft, for example a train, in particular a high-speed train.
    权利要求:
    Claims (15)
    [1" id="c-fr-0001]
    1 / - Method for ventilating a vehicle dynamic air channel (25), said dynamic air channel (25) comprising:
    - a dynamic air inlet (24) capable of receiving a flow of air at dynamic pressure under the effect of a movement of the vehicle,
    - At least one heat exchanger (20) arranged to be able to receive at least part of said dynamic air flow, process in which the dynamic air channel is equipped with at least one injection tube (29) arranged for be able to be supplied with compressed air delivered by sources (13, 17) of compressed air from the vehicle, characterized in that the dynamic air channel (25) is equipped with at least one injection tube (29) , called multiple injection tube (29):
    - comprising a plurality of compressed air inlets (34, 38) and a plurality of compressed air outlet nozzles (44, 48), each nozzle (44, 48) being connected to at least one of said inlets (34 , 38) of compressed air,
    - whose said compressed air inlets (34, 38) are connected to a plurality of sources (13, 17) of compressed air from the vehicle,
    - a first nozzle (44) of which is connected to at least one first compressed air inlet (34) connected to at least one first source of compressed air (13) from the vehicle, this first nozzle (44) being able to receive compressed air delivered by at least one such source (13) of compressed air from the vehicle,
    - of which at least one nozzle (48), called the second nozzle (48), distinct from the said first nozzle (44), is:
    o isolated from each first compressed air inlet (34), o connected to at least one inlet, called second compressed air inlet (38):
    separate from each first compressed air inlet (34), and connected to at least one source of compressed air from the vehicle, called second source of compressed air (17), separate from each first source of compressed air (13) , each second nozzle (48) being able to receive compressed air supplied by at least one such second source (17) of compressed air, without being able to receive compressed air supplied by any first source of compressed air (13) .
    [2" id="c-fr-0002]
    2 / - Method according to claim 1 characterized in that each nozzle (44, 48) of a multiple injection tube (29) is connected to a single inlet (34, 38) of compressed air from this tube (29 ) of multiple injection and in that each compressed air inlet (34, 38) of this multiple injection pipe (29) is connected to a single source of compressed air (13, 17) of the vehicle, each nozzle (44, 48) of this multiple injection tube (29) can only receive compressed air supplied by a single source (13, 17) of compressed air from the vehicle.
    [3" id="c-fr-0003]
    3 / - Method according to any one of claims 1 or 2 characterized in that each source of compressed air (13, 17) of the vehicle is connected to a single inlet (34, 38) of compressed air from a tube (29) multiple injection.
    [4" id="c-fr-0004]
    4 / - Method according to any one of claims 1 to 3 characterized in that at least one rotary compressor of an environmental control device of at least one cabin of the vehicle is connected to at least one inlet of a horn (29) multiple injection.
    [5" id="c-fr-0005]
    5 / - Environmental control device for at least one vehicle cabin (11) comprising:
    - a plurality of sources (13, 17) of compressed air,
    - at least one dynamic air channel (25) comprising:
    o a dynamic air inlet (24) capable of receiving a flow of air at dynamic pressure under the effect of a displacement of the vehicle, o at least one heat exchanger (20) arranged to be able to receive at least a portion of said dynamic air flow, o at least one injection nozzle (29) arranged to be able to be supplied with compressed air supplied by at least part of said sources of compressed air, characterized in that at least one channel (25 ) of dynamic air comprises at least one injection tube (29), called multiple injection tube (29):
    - comprising a plurality of compressed air inlets (34, 38) and a plurality of compressed air outlet nozzles (44, 48), each nozzle (44, 48) being connected to at least one of said inlets (34, 38) of compressed air,
    - whose said compressed air inlets (34, 38) are connected to a plurality of said compressed air sources (13, 17),
    - a first nozzle (44) of which is connected to at least one first inlet (34) of compressed air connected to at least one first source of compressed air (13), this first nozzle (44) being able to receive air tablet delivered by at least one such first source (13) of compressed air,
    - of which at least one nozzle (48), called the second nozzle (48), distinct from the said first nozzle (44), is:
    o isolated from each first compressed air inlet (34), o connected to at least one inlet, called second compressed air inlet (38):
    separate from each first compressed air inlet (34), and connected to at least one source of compressed air, called second source of compressed air (17), separate from each first source of compressed air (13), each second nozzle (48) capable of receiving compressed air supplied by at least one such second source (17) of compressed air, without being able to receive compressed air supplied by any first source of compressed air (13).
    [6" id="c-fr-0006]
    6 / - Device according to claim 5 characterized in that each nozzle (44, 48) of a multiple injection tube (29) is connected to a single inlet (34, 38) of compressed air from this tube (29 ) of multiple injection and in that each compressed air inlet (34, 38) of this multiple injection horn (29) is connected to a single source of compressed air (13, 17) of the vehicle, each nozzle (44, 48) of this multiple injection tube (29) can only receive compressed air supplied by a single source (13, 17) of compressed air from the vehicle.
    [7" id="c-fr-0007]
    7 / - Device according to any one of claims 5 or 6 characterized in that each source of compressed air (13, 17) of the vehicle is connected to a single inlet (34, 38) of compressed air from a tube (29) multiple injection.
    [8" id="c-fr-0008]
    8 / - Device according to one of claims 5 to 7 characterized in that at least one of said first and second sources of compressed air (13, 17) is a rotary compressor.
    [9" id="c-fr-0009]
    9 / - Device according to one of claims 5 to 8 characterized in that at least one multiple injection tube (29) has at least a first central nozzle (44) connected to said first air inlet (34) compressed and at least one series of second peripheral nozzles (48) connected to a second compressed air inlet (38) and extending around each first central nozzle (44).
    [10" id="c-fr-0010]
    10 / - Device according to one of claims 5 to 9 characterized in that each multiple injection tube (29) comprises:
    - an outlet plenum (31) arranged to be able to receive the compressed air delivered by each nozzle (44, 48),
    - An air inlet, called low pressure air inlet (32), arranged to receive air from the dynamic air inlet (24) of the dynamic air channel (25) and the circulating in said plenum (31), said nozzles (44, 48) and said low pressure air inlet (32) being arranged so that the compressed air from any of the nozzles (44, 48) can mix in said plenum (31) with the air supplied by said low pressure air inlet (32) by forming a flow of mixing air causing ventilation of the dynamic air channel (25).
    [11" id="c-fr-0011]
    11 / - Device according to claim 10 characterized in that said low pressure air inlet (32) is a radial air inlet to the nozzles (44, 48) of the multiple injection tube (29).
    [12" id="c-fr-0012]
    12 / - Device according to any one of claims 5 10 or 11 characterized in that the dynamic air channel (25) is provided with a pipe (54) bypassing said injection tube (29), this bypass line (54) connecting to said plenum (31) an area of the dynamic air channel (25) upstream of said low pressure air inlet (32).
    [13" id="c-fr-0013]
    13 / - Device according to claim 12 characterized in that said pipe (54) bypass is provided with a valve (55) adapted for:
    - allow air circulation in the bypass pipe (54) when none of the compressed air inlets (34, 38) is supplied with compressed air,
    - Allow air circulation in the low pressure air inlet (32) of the injection tube (29) when at least one of the compressed air inlets (34, 38) is
    15 supplied with compressed air.
    [14" id="c-fr-0014]
    14 / - Device according to one of claims 10 to 13 characterized in that said plenum (31) communicates with an air outlet (26) from the dynamic air channel to the atmosphere outside the vehicle.
    [15" id="c-fr-0015]
    15 / - Vehicle - in particular an aircraft - characterized in that it comprises at least one environmental control device according to one of claims 5 to 14.
    1/3
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    同族专利:
    公开号 | 公开日
    US20180237143A1|2018-08-23|
    EP3366588A1|2018-08-29|
    FR3063042B1|2019-07-05|
    US10556693B2|2020-02-11|
    EP3366588B1|2020-04-01|
    ES2804274T3|2021-02-05|
    引用文献:
    公开号 | 申请日 | 公开日 | 申请人 | 专利标题
    US2870698A|1957-04-30|1959-01-27|United Aircraft Corp|Recirculating flow aircraft air conditioning system|
    US3842720A|1973-03-29|1974-10-22|Piper Aircraft Corp|Jet pump for aircraft cabin pressurization system|
    US20070113579A1|2004-08-25|2007-05-24|Claeys Henry M|Low energy electric air cycle with portal shroud cabin air compressor|
    US7797962B2|2005-08-08|2010-09-21|Liebherr-Aerospace Lindenberg Gmbh|Method of operating an aircraft system|
    EP2062818A1|2007-11-26|2009-05-27|Honeywell Normalair-Garrett Limited|Environmental control system|
    US9205925B2|2011-11-11|2015-12-08|Hamilton Sundstrand Corporation|Turbo air compressor|
    US9003814B2|2011-11-11|2015-04-14|Hamilton Sundstrand Corporation|Turbo air compressor with pressure recovery|
    EP2947012B1|2014-05-19|2017-07-05|Airbus Operations GmbH|Aircraft air conditioning system and method of its operation|
    EP3444189B1|2014-09-19|2020-06-17|Airbus Operations GmbH|Aircraft air conditioning system and method of operating an aircraft air conditioning system|
    US20160214722A1|2015-01-23|2016-07-28|Hamilton Sundstrand Corporation|Ram air flow modulation valve|US10532631B2|2017-03-29|2020-01-14|Ford Global Technologies, Llc|Acoustic air duct and air extraction system including a plurality of channels having an expansion chamber|
    FR3070967B1|2017-09-14|2019-08-30|Airbus Operations|COMPACT THERMAL EXCHANGE DEVICE INCORPORATED IN AN AIRCRAFT MAT|
    FR3098247B1|2019-07-04|2021-06-25|Safran Aircraft Engines|TURBOMACHINE JET TRUMP|
    EP3945027A1|2020-07-30|2022-02-02|Hamilton Sundstrand Corporation|Aircraft environmental control system|
    法律状态:
    2018-02-27| PLFP| Fee payment|Year of fee payment: 2 |
    2018-08-24| PLSC| Publication of the preliminary search report|Effective date: 20180824 |
    2020-02-19| PLFP| Fee payment|Year of fee payment: 4 |
    2021-02-23| PLFP| Fee payment|Year of fee payment: 5 |
    2022-02-19| PLFP| Fee payment|Year of fee payment: 6 |
    优先权:
    申请号 | 申请日 | 专利标题
    FR1751443A|FR3063042B1|2017-02-23|2017-02-23|METHOD FOR VENTILATION OF A DYNAMIC AIR CHANNEL AND ENVIRONMENTAL CONTROL DEVICE AND VEHICLE IMPLEMENTING SAID METHOD|
    FR1751443|2017-02-23|FR1751443A| FR3063042B1|2017-02-23|2017-02-23|METHOD FOR VENTILATION OF A DYNAMIC AIR CHANNEL AND ENVIRONMENTAL CONTROL DEVICE AND VEHICLE IMPLEMENTING SAID METHOD|
    ES18157674T| ES2804274T3|2017-02-23|2018-02-20|Ventilation method of a dynamic air channel and vehicle and environmental control device to carry out this method|
    EP18157674.5A| EP3366588B1|2017-02-23|2018-02-20|Method for ventilating a dynamic air channel and environmental control device and vehicle using said method|
    US15/902,587| US10556693B2|2017-02-23|2018-02-22|Method for ventilating a ram air channel and environmental control device and vehicle implementing this method|
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