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    • 专利摘要:
    The invention relates to a method and a device for thermal control of a plurality of cabins (13 to 18) of a vehicle from a mixing chamber (12) fed with air from at least one device ( 19, 20) at least the temperature is controlled, each cabin being supplied with air by a supply line specific to this cabin. At least one cabin (13, 14, 15, 17, 18) is supplied with air at a temperature adjusted by at least one individual heat exchanger (64, 75, 86, 108, 119) associated with said pipe (63, 74, 85 , 96, 107, 118) proper supply to this cabin, a second circuit is supplied by a heat transfer fluid from at least one loop (31, 51) heat transfer fluid thermal control of the vehicle. It extends to a vehicle equipped with at least one thermal control device according to the invention.
    公开号:FR3065518A1
    申请号:FR1753435
    申请日:2017-04-20
    公开日:2018-10-26
    发明作者:Guillaume GALZIN
    申请人:Liebherr Aerospace Toulouse SAS;
    IPC主号:
    专利说明:

    Holder (s): LIEBHERR-AEROSPACE TOULOUSE SAS Simplified joint-stock company.
    Extension request (s)
    Agent (s): CABINET BARRE LAFORGUE & ASSOCIES.
    METHOD AND DEVICE FOR THERMAL CONTROL OF A PLURALITY OF CABS OF A VEHICLE.
    FR 3 065 518 - A1
    The invention relates to a method and a device for thermal control of a plurality of cabins (13 to 18) of a vehicle from a mixing chamber (12) supplied with air from at least one device ( 19, 20) of air supply of which at least the temperature is controlled, each cabin being supplied with air by a supply pipe specific to this cabin. At least one cabin (13, 14, 15, 17, 18) is supplied with air at a temperature adjusted by at least one individual exchanger (64, 75, 86, 108, 119) associated with said pipe (63, 74, 85 , 96,107,118) supply specific to this cabin, a second circuit of which is supplied by a heat transfer fluid coming from at least one loop (31, 51) of thermal regulation with heat transfer fluid from the vehicle. It extends to a vehicle provided with at least one thermal control device according to the invention.

    i
    METHOD AND DEVICE FOR THERMAL CONTROL OF A PLURALITY OF VEHICLE CABS
    The invention relates to a method and a device for thermal control of a plurality of cabs of a vehicle, in particular an aircraft. It also extends to a vehicle, in particular an aircraft, provided with at least one thermal 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 at least the air temperature must be controlled. It can therefore be either a passenger reception area, a cockpit, a hold, a cargo loading space ... The expression "thermal control" designates the fact of control at least the air temperature in a cabin. The expression “thermal regulation loop” designates any device comprising at least one closed circuit in which at least one heat transfer fluid circulates in contact with at least one cold source so as to be able to exchange calories with this cold source and in contact with '' at least one hot spring so that you can exchange calories with this hot source.
    Vehicles are most often fitted with at least one device, called an environmental control device or system (ECS), allowing at least one thermal control of each cabin of the vehicle. Each cabin is supplied with air from a mixing chamber allowing in particular the mixing of recirculating air coming from all or part of the cabins with the air delivered by each environmental control device.
    In the case of aircraft in particular, the environmental control devices are most often made on the basis of at least one air cycle machine also making it possible to control the air pressure. A vehicle can also be provided with at least one thermal regulation loop with liquid / gas two-phase heat-transfer fluid (in particular a so-called vapor cycle device (VCS)) and / or at least one thermal regulation loop with single-phase heat-transfer liquid , for example for cooling on-board equipment such as electronic power equipment and / or refrigerators, or for heating on-board equipment such as cooking ovens or the like.
    Numerous proposals, especially theoretical ones, have been formulated for the optimization of thermal management on board a vehicle from different cold and hot sources and different thermal loops with air cycle and / or with steam cycle and / or single-phase liquid cycle available on board the vehicle.
    The fact remains that the problem of thermal control of a plurality of cabs of the same vehicle from the same mixing chamber is not, in practice, optimized from the energy point of view.
    In fact, in the most rudimentary known systems, the air leaving the mixing chamber is supplied indifferently in the various cabs of the vehicle. However, these different cabins having in practice different thermal needs, the stabilized temperature in each cabin is different from one cabin to another and cannot be regulated as a function of a set temperature specific to each cabin.
    In certain more advanced known systems (cf. for example EP1701884), the thermal control of several cabins is carried out by controlling the temperature of the air leaving the mixing chamber as a function of the cab having the highest power demand. cold, each other cabin being supplied with air coming from the mixing chamber heated by an electric heater interposed between the mixing chamber and the cabin, or by injection of hot air coming from the propulsion engines of the vehicle. The temperature within each cabin can be regulated according to the specific thermal needs of each cabin, and possibly according to a set temperature specific to each cabin. However, these known systems in which in cooling mode the air initially cooled by an environmental control system is heated to adjust its temperature to the needs of at least one cabin induce an energy waste which should be avoided. In other known systems, it has been proposed to supply each cabin from an environmental control system by means of an evaporative cooling water injector and an electric heater specific to each cabin. These systems are also not very efficient from the point of view of their energy efficiency, complex and costly in terms of equipment and control logic.
    The invention therefore aims to overcome all of these drawbacks. It aims in particular to propose a method and a device for thermal control allowing an individual thermal control of each cabin of a plurality of cabins of a vehicle - in particular of an aircraft - from the same mixing chamber in improved energy efficiency conditions, in a simple, reliable and inexpensive way.
    It also aims to propose such a method and such a thermal control device which are operational in all the conditions of use of the vehicle, in particular in all the operating and flight conditions of an aircraft (on the ground, at takeoff, in high altitude flight, low altitude flight, landing, ...).
    It aims in particular to propose such a method and such a thermal control device which does not require the use of electric heaters or the injection of hot air taken from the propulsion engines of the vehicle or of water evaporated in the pipes. specific supply to each cabin for the individual heating and / or cooling of the air coming from the mixing chamber.
    To do this, the invention relates to a method of thermal control of a plurality of cabs of a vehicle from a mixing chamber supplied with air from at least one air supply device of which at least the temperature is controlled, each cabin being supplied with air:
    - from the mixing chamber,
    - by a supply line specific to this cabin,
    - independently of each other cabin, characterized in that:
    - at least one cabin is supplied with air at a temperature adjusted by at least one heat exchanger, said individual exchanger, associated with said supply line specific to this cabin,
    - Air from the mixing chamber passing through a first circuit of each individual exchanger associated with said supply line specific to a cabin and independently supplying said cabin, this first circuit being interposed between said cabin and the mixing chamber on said supply line specific to said cabin,
    - at least a second circuit of at least one individual exchanger associated with a supply line specific to a cabin is supplied with a heat transfer fluid coming from at least one thermal regulation loop of the vehicle,
    - this heat transfer fluid being selected:
    o among:
    at least one heat transfer fluid taken from a thermal regulation loop of the vehicle at a temperature higher than the temperature of the air coming from the mixing chamber, at least one heat transfer fluid taken from a thermal regulation loop of the vehicle at a temperature lower than the temperature of the air coming from the mixing chamber, o so that each individual exchanger associated with the supply line specific to said cabin individually adjusts the temperature of the air supplying said cabin as a function of a temperature deposit for said cabin.
    The invention extends to a device suitable for implementing a method according to the invention. It therefore also relates to a device for thermal control of a plurality of cabs of a vehicle comprising:
    - a mixing chamber,
    - at least one air supply device connected to the mixing chamber to supply it with temperature-controlled air,
    - a thermal management automation adapted to control at least the temperature of the air supplied by each air supply device to the mixing chamber as a function of at least one set temperature of at least one cabin of the vehicle,
    - each cabin being connected to the mixing chamber by a supply line specific to this cabin so as to be able to be supplied with air from the mixing chamber independently of each other cabin, characterized in that:
    - at least one heat exchanger, said individual exchanger, is associated with at least one supply line specific to a cabin,
    - each individual exchanger includes:
    o a first circuit interposed, between said cabin and the mixing chamber, on said supply line specific to said cabin so that it can be traversed by air coming from the mixing chamber and supply said cabin, o a second circuit connected to at least one thermal regulation loop with heat transfer fluid of the vehicle in order to be able to be supplied by this heat transfer fluid,
    - Said thermal management automation is adapted to supply at least a second circuit of at least one individual exchanger associated with a supply line specific to a cabin by a heat transfer fluid coming from at least one thermal regulation loop of the vehicle ,
    - said thermal management automation is suitable for selecting this heat transfer fluid:
    o among:
    at least one heat transfer fluid taken from a thermal regulation loop of the vehicle at a temperature higher than the temperature of the air coming from the mixing chamber, at least one heat transfer fluid taken from a thermal regulation loop of the vehicle at a temperature lower than the temperature of the air coming from the mixing chamber, o chosen so that each individual exchanger associated with the supply line specific to said cabin individually adjusts the temperature of the air supplying said cabin according to a set temperature for said cabin.
    The invention also extends to a thermal control process implemented in a thermal control device according to the invention.
    A vehicle such as an aircraft is generally systematically provided with at least one thermal regulation loop with heat transfer fluid - in particular a monophasic heat transfer fluid, which can be in particular a monophasic heat transfer liquid or air -, for cooling. equipment on board the vehicle such as electrical or electronic equipment, for example for cooling the power electronics. Such a single-phase heat transfer fluid thermal regulation loop is available and operational on board the vehicle under all operating conditions, in particular the flight, of the latter. It is associated with hot sources (equipment to be cooled, condenser of a two-phase vapor cycle loop (VCS) ...) and to cold sources (equipment to be heated, evaporator of a two-phase vapor cycle loop (VCS) , skin exchangers ...). Consequently, in a method and a device according to the invention, the heat transfer fluid can be taken from such a thermal regulation loop at different temperatures, according to the needs for individual adjustment of the temperature of each cabin. The use of such a heat transfer fluid of a thermal regulation loop is also extremely simple, makes it possible to use equipment already on board, and therefore minimizes the impact in terms of weight and size of the adaptation of the vehicle for implementing a method according to the invention.
    In a method and a device according to the invention, said set temperature for at least one cabin of the vehicle can in particular be chosen from a set temperature of the air inside a cabin of the vehicle, a temperature of setpoint of the air supplying a vehicle cabin, a setpoint air temperature inside several cabins of the vehicle, a setpoint air temperature supplying several cabins of the vehicle, and values determined from several of these set temperatures (in particular an average value of a plurality of these set temperatures). In certain preferred embodiments, said set temperature is a set temperature of the air supplying said cabin.
    According to the different possible embodiments, nothing prevents said thermal regulation loop with heat transfer fluid from being wholly or partly associated with at least one device for supplying air to the mixing chamber. However, in certain advantageous embodiments of a method and of a device according to the invention, said thermal regulation loop is distinct and independent of each air supply device of the mixing chamber.
    Furthermore, the invention applies with all possible embodiments of devices) for supplying air to the mixing chamber. However, in certain advantageous embodiments according to the invention, each air supply device for the mixing chamber is an air cycle device, that is to say comprising at least one air cycle machine . Such an air cycle machine comprises at least one compressor and at least one turbine. At least one intermediate heat exchanger is interposed between a compressor and a turbine of such an air cycle machine. Advantageously, a water extraction loop is provided downstream of the turbine of such an air cycle machine. At least one electric motor can be associated with a compressor of such an air cycle machine.
    In addition, the temperature of the air supplied to the mixing chamber by each air supply device can be controlled as a function of at least one set temperature for at least one cabin of the vehicle - in particular according to a set temperature. for each cabin of the vehicle. Such a setpoint temperature for at least one cabin of the vehicle used for controlling the temperature of the air supplied to the mixing chamber can in particular be chosen from a setpoint temperature of the air inside a vehicle cabin, a target air temperature supplying a vehicle cabin, an air target temperature inside several vehicle cabins, a target air temperature supplying several vehicle cabins, and values determined from several of these set temperatures (in particular an average value of a plurality of these set temperatures).
    This control of the temperature of the air delivered to the mixing chamber by each air supply device can be carried out by an automatic thermal management system - in particular according to closed-loop regulation. Such an automatic thermal management also takes into account the different air flows that can be introduced into the mixing chamber, in particular recirculation air flows from one and / or the other of the vehicle cabins. Such a thermal management automation is advantageously adapted to regulate at least the temperature of the air leaving the mixing chamber as a function of at least one predetermined regulation criterion, in particular at least one set temperature for at least one cabin. of the vehicle.
    In a method and a device according to the invention, the temperature of the air supplied to at least one cabin - in particular in each cabin - can be adjusted individually, that is to say independently of the temperature of the air supplied the other cabins, thanks to at least one simple heat exchanger supplied with heat transfer fluid at an appropriate temperature.
    There is nothing to prevent the provision of at least one supply line specific to a cabin directly supplying the cabin with air coming from the mixing chamber, without any individual intermediate exchanger. For example, a cabin with the lowest heat input requirements can be directly supplied with air from the mixing chamber, the individual adjustment of the temperature of the air supplying this cabin not being necessary.
    However, in certain embodiments of a method according to the invention, each cabin of said plurality of cabins is supplied with air at a temperature capable of being adjusted by at least one individual exchanger associated with said clean supply line. to this cabin. Similarly, in a device according to the invention at least one individual exchanger is associated with each supply line specific to a cabin.
    Furthermore, nothing prevents the provision of the temperature of the air supplying at least one cabin to be individually adjusted only in one direction relative to the temperature of the air coming from the mixing chamber, for example in cooling mode. only in the direction of a temperature decrease, or only in the direction of a temperature increase in heating mode. However, in certain preferred embodiments of the invention, the temperature of said heat transfer fluid is chosen so as to be able to individually adjust the temperature of the air supplying said cabin either in the direction of a decrease in temperature, or in the direction of an increase in temperature compared to the temperature of the air coming from the mixing chamber. Thus, advantageously and according to the invention, said heat transfer fluid is selected from:
    - at least one fluid - in particular at least one heat transfer liquid - taken from a thermal regulation loop of the vehicle at a temperature higher than the temperature of the air coming from the mixing chamber, when said set temperature for said cabin is higher than the temperature of the air coming from the mixing chamber,
    - at least one fluid - in particular at least one heat transfer liquid - taken from a thermal regulation loop of the vehicle at a temperature below the temperature of the air coming from the mixing chamber, when said set temperature for said cabin is below the temperature of the air from the mixing chamber.
    Said temperature of the air coming from the mixing chamber can be chosen from a temperature measured in the mixing chamber ίο by at least one temperature sensor, and a temperature determined by calculation - in particular by said thermal management automation -.
    In addition, in certain embodiments according to the invention, each air supply device for the mixing chamber and said heat transfer fluid are chosen and adapted so that the temperature of said heat transfer fluid and said temperature of the air coming from the mixing chamber is different from each other, in particular differ from each other in absolute value by a difference value greater than a predetermined threshold value. This predetermined threshold value is chosen in particular to ensure sufficient heat exchange between the two circuits of each individual exchanger, and is advantageously greater than 1 ° C, in particular between 2 ° C and 10 ° C, for example of the order 5 ° C. Thus, in these embodiments, said thermal management automation is suitable for controlling the temperature of the air supplied to the mixing chamber by each air supply device, and the supply of each second circuit supplied with heat transfer fluid so that said heat transfer fluid is supplied in the second circuit at a temperature having a difference with the temperature of the air coming from the mixing chamber which is greater, in absolute value, than said predetermined threshold value.
    Said thermal management automation is thus adapted to control on the one hand each air supply device of the mixing chamber, on the other hand the supply of each second circuit of each individual exchanger by a heat transfer fluid taken from a loop thermal regulation of the vehicle, provided that this heat transfer fluid is at a temperature having a difference greater than said predetermined threshold value with respect to the temperature of the air coming from the mixing chamber. This minimum temperature difference between the air at the outlet of the mixing chamber and the heat transfer fluid supplied to each individual exchanger allows in practice to ensure effective thermal control, without risk of instability.
    Nothing prevents several individual exchangers from being associated with the same supply line specific to a cabin. For example, it is possible to provide, for the same supply line specific to a cabin, a first individual exchanger adapted to receive a heat transfer fluid at a temperature higher than the temperature of the air coming from the mixing chamber so as to increase the temperature of the air supplying the cabin relative to the temperature of the air coming from the mixing chamber, and a second individual exchanger adapted to receive a heat-transfer fluid at a temperature below the temperature of the air coming from of the mixing chamber so as to reduce the temperature of the air supplying the cabin relative to the temperature of the air coming from the mixing chamber. It is also possible to provide several individual exchangers associated with the same supply line, in particular at least a first individual exchanger adapted to make a rough temperature adjustment (the second circuit of such a first individual exchanger being supplied with heat transfer fluid. whose characteristics are adapted to carry out such a rough temperature adjustment), and at least one second individual exchanger adapted to carry out a fine temperature adjustment (the second circuit of such a first individual exchanger being supplied with heat-transfer fluid whose characteristics are suitable for making such a fine temperature adjustment). It is also possible to provide several similar individual exchangers associated with the same supply line for redundancy purposes, to compensate for a possible failure of one of these individual exchangers.
    However, in certain preferred embodiments, at most one individual exchanger is associated with each supply line specific to a cabin.
    In certain possible embodiments, said second circuit of such a single individual exchanger associated with a supply line specific to the cabin can be supplied with a heat transfer fluid coming from a single sample from a single thermal regulation loop of the vehicle, that is to say at a single temperature, the adjustment of the temperature of the air supplying the cabin being possible only in one direction of temperature variation, either a decrease in temperature, or an increase in temperature in relation to the temperature of the air coming from the mixing chamber. That said, preferably, said second circuit of each single individual exchanger associated with a clean supply line to the cabin is supplied with heat transfer fluid by means of selective supply from a sample chosen from a plurality of samples of at least one thermal regulation loop of the vehicle. Said plurality of samples can be made up of several samples from the same vehicle thermal regulation loop, or on the contrary can comprise at least several samples taken from several separate thermal regulation loops of the vehicle.
    Advantageously in certain embodiments according to the invention, the second circuit of each individual exchanger associated with a supply line specific to a cabin is itself individually supplied with heat transfer fluid by supply means which are specific to it, c that is to say independently of the supply of heat-transfer fluid to each other second circuit of each individual exchanger associated with the same supply line or with another supply line (specific to another cabin). However, it is possible to provide supply means common to several second circuits of several individual exchangers associated with the same supply line specific to the same cabin, or common to several second circuits of several individual exchangers associated respectively with several separate supply lines specific to several separate cabins. For example, the second circuits of several individual coarse adjustment exchangers associated with separate supply lines can be supplied by common supply means, that is to say by the same multi-way valve, and therefore by a same heat transfer fluid.
    In certain embodiments in accordance with the invention, these means for supplying each second circuit with heat transfer fluid consist of a multi-way valve - in particular a three-way valve - controlled by said thermal management automation. Thus, advantageously in a method according to the invention each second circuit is supplied with heat transfer fluid by means of a multi-way valve - in particular a three-way valve - having an outlet connected to the second circuit, a first inlet connected to a first sample of heat transfer fluid from a thermal regulation loop of the vehicle and at least one second inlet - in particular a single second inlet - connected to a second sample of heat transfer fluid from a thermal regulation loop of the vehicle, the second sample being adapted to be able to deliver heat transfer fluid at a temperature different from the temperature of the heat transfer fluid that can be delivered by the first sample. In addition, advantageously and according to the invention each second circuit is supplied with heat transfer fluid by means of a multi-way valve - in particular a three-way valve - connected to at least two separate withdrawals - in particular to two separate withdrawals - d '' the same heat transfer fluid at different temperatures of the same thermal regulation loop of the vehicle.
    In a device according to these embodiments of the invention each second circuit is connected to at least one thermal regulation loop of the vehicle by means of a multi-way valve - in particular a three-way valve - having an outlet connected to the second circuit, a first inlet connected to a first heat transfer fluid sample from a thermal regulation loop of the vehicle and at least a second input - in particular a single second input connected to a second heat transfer fluid sample from a thermal regulation loop of the vehicle, the second sample being adapted to be able to deliver heat transfer fluid at a temperature different from the temperature of the heat transfer fluid that can be delivered by the first sample. In addition, advantageously and according to the invention, the first sample and each second sample are separate samples from the same thermal regulation loop of the vehicle.
    In particular, in certain embodiments, at least one - in particular each - multi-way valve is a three-way valve having a first inlet connected to a first heat transfer fluid sample and a second inlet connected to a second heat transfer fluid sample, and a output connected to one or other of its two inputs.
    In certain embodiments, advantageously and according to the invention, each multi-way valve - in particular each three-way valve - is controlled according to a so-called alternating control mode, that is to say so that, in position open to the valve, its output is connected to one or other of its inputs, and to only one of its inputs. Thus, in the open position, the valve delivers all or part of the flow entering one or the other only of its inputs. It should be noted, however, that each multi-way valve is preferably a proportional valve, that is to say that, in the open position, the flow rate delivered by the outlet can be adjusted according to the valve opening position. In the closed position, the valve does not deliver any flow.
    Advantageously and according to the invention, the first sample and the second sample are two separate samples of the same heat transfer fluid at two different temperatures from the same thermal regulation loop of the vehicle. Indeed, a heat transfer fluid at low temperature and a heat transfer fluid at high temperature are sufficient to individually adjust the temperature of the air supplying a cabin.
    However, there is nothing to prevent it from being provided that each second circuit can be supplied by more than two separate samples of heat transfer fluid, that is to say at more than two different temperatures, coming from one and the same thermal regulation loop of the vehicle, or on the contrary of several distinct thermal regulation loops of the vehicle. This variant makes it possible in particular to maintain the thermal control of the cabins in the event of unavailability of a heat transfer fluid sample on a thermal regulation loop, either because of a malfunction on this thermal regulation loop, or more generally to avoid such a withdrawal to the detriment of the performance of the thermal regulation loop (for example under certain conditions of use of the vehicle, in particular in certain flight domains when it is an aircraft).
    In particular, in certain embodiments of the invention, each thermal regulation loop of the vehicle may advantageously be a thermal regulation loop with single-phase heat-transfer fluid (that is to say which remains in the same physical state (liquid or gas) at any point on the loop). Such a single-phase heat transfer fluid can in particular be chosen from a heat transfer liquid and air.
    In certain advantageous embodiments of the invention, at least one thermal regulation loop whose heat transfer fluid is used to supply at least one individual exchanger can in particular be a cooling loop for electronic equipment of the vehicle, for example circuits power electronics. It should be noted that nothing prevents the provision that several - in particular all - the second circuits of several - in particular all - the individual exchangers are supplied from a single thermal regulation loop of the vehicle. However, nothing prevents the provision of at least one individual exchanger, the second circuit of which is supplied by a first heat transfer fluid from a first thermal regulation loop, and at least one other individual exchanger, the second circuit of which is supplied by a second heat transfer fluid from a second thermal regulation loop distinct from said first thermal regulation loop.
    The individual adjustment of the temperature in one direction as in the other (individual heating or cooling from the temperature of the air supplied by the mixing chamber) of the air supplying each cabin of the vehicle in a process and a device according to the invention allows in practice to optimize the energy consumption induced by the thermal control of the various cabs of the vehicle. The logic implemented to control the temperature of the air in the mixing chamber and to make this individual temperature adjustment can be the subject of very many variant embodiments.
    For example, in certain possible embodiments of the invention, the temperature of the air supplied to the mixing chamber by each air supply device is determined as a function of a minimum value of the heat input requirements of the different vehicle cabs. This minimum value can in particular be determined by the smallest difference, in absolute value, between at least one air temperature measured for a cabin and said set temperature for this cabin. In the corresponding embodiments of a device according to the invention, said thermal management automation is suitable for determining a minimum value of the heat input requirements of the various cabs of the vehicle, and for controlling the temperature of the air delivered to the room. mixing by each air supply device according to this minimum value. In particular, each cabin being provided with at least one sensor for measuring an air temperature for this cabin, said thermal management automation is adapted to control the temperature of the air delivered to the mixing chamber by each device. air supply as a function of the smallest difference, in absolute value, between a temperature measured for a cabin and said set temperature for this cabin.
    Said air temperature measured for each cabin used to determine said smallest difference, that is to say the cabin having the lowest need for heat input, can be chosen from a temperature of the air supplying said cabin and a air temperature inside said cabin. When said set temperature for the cabin is a set temperature of the air supplying the cabin, said measured air temperature is also the temperature of the air supplying this cabin. When said set temperature for the cabin is a set temperature for the air inside the cabin, said measured air temperature is also the temperature measured inside the cabin.
    Other variants are possible, for example by controlling the temperature of the air supplied to the mixing chamber by each air supply device as a function of an average value of the heat input requirements of different cabins and / or as a function of an average setpoint temperature value for different cabins and / or as a function of average temperature values measured for different cabins.
    The air leaving the mixing chamber thus makes it possible to control, without individual adjustment, the temperature of this cabin requiring the lowest heat input, that is to say having the smallest difference, in absolute value. , between said temperature measured for the cabin and said set temperature for this cabin. The temperature of the air supplying such a cabin requiring the lowest heat input does not have to be adjusted individually, so that if this cabin is supplied via an individual exchanger, the supply of the second circuit of this individual exchanger can be closed, no heat transfer fluid circulating in this second circuit. In certain embodiments, the supply line specific to this cabin requiring the lower heat input can be free of individual exchanger, if this cabin is always the same whatever the operating conditions of the vehicle.
    The invention also extends to a vehicle - in particular to an aircraft - comprising at least a plurality of cabins, at least one device for thermal control of each plurality of cabins and at least one thermal regulation loop with heat transfer fluid, characterized in which it comprises at least one thermal control device according to the invention. It also extends to a vehicle in which a thermal control method according to the invention is implemented.
    The invention also relates to a thermal control method, a thermal control device and a vehicle characterized in combination by all or some of the characteristics mentioned above or below.
    Other objects, characteristics and advantages of the invention will appear on reading the following description given by way of nonlimiting illustrative example and which refers to the appended figures in which:
    FIG. 1 is a diagram representing an exemplary embodiment of a thermal control device according to the invention,
    FIG. 2 is an example of a general algorithm implemented in a method according to the invention,
    - Figure 3 is an example of algorithm implemented in a method according to the invention for supplying a second circuit of an individual exchanger.
    An example of a thermal control device according to the invention of an aircraft 11 is shown in FIG. 1. This device comprises a mixing chamber 12 supplied by different air flows, this mixing chamber 12 making it possible to supply individual cabins 13 to 18 of the aircraft 11 by different air flows.
    The mixing chamber 12 is supplied in particular by two devices 19, 20 for supplying air at a controlled temperature, each of these devices 19, 20 for supplying air being, for example, an environmental control module (ECS) with a air cycle. Each air supply device 19, 20 has an outlet 21, respectively 22 connected to an inlet 23, respectively 24 of the mixing chamber 12 by a pipe 25, respectively 26, provided with a temperature sensor 27, respectively 28 of air supplied to outlet 21, 22.
    In the example shown, a first device 19 comprises a turbocharger comprising a compressor coupled to a turbine and to a fan, the compressor receiving air from the external environment and / or from any other available air source. , compressing it to deliver it to an intermediate exchanger in which it is cooled before it passes through a water extraction loop, then at the inlet of the turbine, the latter delivering, in cooling mode, an air flow cooled in the mixing chamber 12. In heating mode, the stream of heated compressed air supplied by the compressor can be directly delivered at the outlet of the device 19 in the mixing chamber 12. The second air supply device 20 with controlled temperature shown is similar to the first device 19, except that an electric motor is interposed between the compressor and the turbine for be able to train the latter.
    It goes without saying that all other alternative embodiments of such temperature-controlled air supply devices can be used in the context of the present invention. In particular, nothing prevents the provision of one (or more) air supply device (s) operating solely in heating mode (for example a compressor motor or a heat pump) and / or one (or more) devices ) air supply operating only in cooling mode (i.e. for air conditioning) and / or one (or more) air supply devices comprising at least one thermal regulation loop with two-phase heat transfer fluid (liquid / vapor) and / or one (or more) devices for supplying air comprising at least one thermal regulation loop with single-phase heat transfer liquid.
    Each temperature controlled air supply device 19, 20 is controlled by a thermal management automation (not shown) receiving the signals delivered by each temperature measurement sensor and comprising in particular in general a servo-control of the air temperature at the output of the device 19, 20 as a function of a required temperature, determined moreover by the automatic thermal management. The general characteristics of such a thermal management automation (formed by a vehicle on-board computer and its various interfaces with the components it controls: valves, temperature sensors, motors, compressors, pumps ...) and its various possible programming modes are well known in themselves and not to be described in detail, only its characteristics specific to the present invention being described below.
    The mixing chamber 12 is also generally supplied with recirculation air coming from at least one of the cabins 13 to 18 by at least one recirculation line 29. It can also be supplied by any other air flow available on board the aircraft 11 and in particular by any other air flow allowing recovery of thermal energy and / or possibly by fresh air coming from the 'outside.
    A temperature sensor 30 connected to the thermal management automation makes it possible to measure the temperature of the mixing air inside the mixing chamber 12.
    The aircraft 11 also comprises at least one loop 31, 51 5 for thermal regulation with a single-phase heat transfer liquid, arranged and adapted for the thermal control of equipment on board the aircraft 11 other than the cabins 13 to 18 proper. . Such a single-phase heat-transfer liquid thermal regulation loop is generally distinct from each temperature-controlled air supply device 19, 20 and independent of these air supply devices 19, 20, in the sense that it does not constitute neither a hot nor cold source for these devices 19, 20.
    In the example shown, the aircraft 11 comprises two loops 31, 51 for thermal regulation with single-phase heat transfer liquid.
    A first loop 31 includes a reservoir 33 of coolant 15, a pump 34, a heat exchanger, said cooling exchanger 35, associated with a hot source 32 to be cooled, consisting for example of on-board electronic power equipment, and two sources cold for cooling the heat transfer liquid, namely a heat exchanger 36 called skin exchanger, that is to say receiving air outside the vehicle (for example RAM air at dynamic pressure under the effect of the movement of the vehicle), and a heat exchanger 37 acting as an evaporator in a loop 40 for thermal regulation with two-phase heat transfer fluid (VCS).
    This loop 40 with two-phase cycle for example comprises a compressor 38 supplying the fluid in the gaseous state to a heat exchanger 39 acting as a condenser, for example associated with air outside the vehicle as a cold source, a reservoir 41 of fluid and a pressure reducing valve 42 supplying the evaporator 37, the output of which supplies the compressor 38. It goes without saying that such a loop 40 with two-phase cycle can be the subject of numerous alternative embodiments.
    The second loop 51 for thermal regulation with a single-phase heat-transfer liquid is similar to the first loop 31 but comprises an additional cold source in the form of a heat exchanger, called recirculation exchanger 52, associated with the recirculation line 29 to cool the recirculation air from at least one cabin of the aircraft 11 before it is supplied to the mixing chamber 12.
    This second loop 51 of single-phase heat-transfer liquid thermal regulation comprises a reservoir 53 of heat-transfer liquid, a pump 54, a heat exchanger, called a heat exchanger 55 for cooling, associated with a hot source 58 to be cooled, consisting for example of on-board electronic equipment power, and three cold sources for cooling the heat transfer liquid, namely, in addition to the recirculation exchanger 52, a heat exchanger 56, said skin exchanger 56, that is to say receiving air outside the vehicle (for example RAM air at dynamic pressure under the effect of the displacement of the vehicle), and a heat exchanger 57 acting as an evaporator in a loop 60 of thermal regulation with two-phase heat transfer fluid (VCS).
    This loop 60 with two-phase cycle is similar to the loop 40 with two-phase cycle associated with the first loop 31 of thermal regulation with single-phase heat transfer liquid.
    In addition, a bypass pipe 59 makes it possible to directly connect the outlet of the recirculation exchanger 52 to the upstream of the pump 54, at least part of the flow rate of the single-phase heat-transfer liquid not circulating in the cooling exchanger 55 nor in the skin exchanger 56. A valve 61 controlled by the thermal management automation is interposed on this pipe
    59 bypass to adjust the flow of liquid passing through the bypass line 59. This bypass pipe 59 makes it possible to prevent the flow of liquid in the cooling exchanger 55 from being too high, taking into account that, moreover, the flow of liquid required for the recirculation exchanger 52 is generally higher than that required in the heat exchanger 55.
    A first cabin 13 (for example the cockpit of the aircraft 11) is connected to the mixing chamber 12 by a pipe 63 for supplying clean air to this cabin 13 via a first circuit of an exchanger of air / liquid heat, said individual exchanger 64. Any heat exchanger allows heat transfer between its first circuit and its second circuit, according to the temperature difference of the flows passing through these two circuits respectively. The individual exchanger 64 thus has a second circuit supplied from a three-way valve 65 by heat transfer liquid withdrawn from the first heat regulation loop 31 with single-phase heat transfer liquid.
    The three-way valve 65 is controlled by the thermal management automation and has a first input connected to a first node 66 for hot removal of the loop 31 downstream of the cooling exchanger 35 allowing the heat-transfer liquid to be withdrawn. relatively high temperature. The three-way valve 65 has a second inlet connected to a second cold sampling node 67 upstream of the cooling exchanger 35 making it possible to withdraw the heat transfer liquid at a relatively low temperature.
    The three-way valve 65 has an outlet connected to the inlet of the second circuit of the individual exchanger 64. The output of this second circuit is connected to a node 72 of the first thermal regulation loop 31 to recycle the heat transfer liquid in this loop, preferably immediately upstream of the pump 34. A temperature sensor 73 makes it possible to measure the temperature at this node 72.
    Thus, the second circuit of the individual exchanger 64 can be supplied, on command of the thermal management automation, either by high temperature heat transfer liquid to heat the air supplied to the cabin 13, or by heat transfer liquid to low temperature to cool the air supplied to the cabin 13. A temperature sensor 68 makes it possible to measure the temperature of the liquid at the first node 66. A temperature sensor 69 makes it possible to measure the temperature at the second node 67. A temperature sensor 70 enables the temperature of the air entering the first cabin 13 to be measured and a temperature sensor 71 enables the interior temperature of the first cabin 13 to be measured.
    The thermal management automation controls in particular the three-way valve 65 as a function of the temperature of the air in the mixing chamber 12 measured by the sensor 30, of the different temperature measurements delivered by the different temperature sensors and of a set temperature adjusted by the crew of the aircraft 11, for example from a thermostat specific to the first cabin 13.
    A second cabin 14 which is for example a passenger cabin is connected to the mixing chamber 12 by a pipe 74 for supplying air clean to this cabin 14 via a first circuit of an air heat exchanger / liquid, said individual exchanger 75. The individual exchanger 75 has a second circuit supplied, like the air / liquid exchanger 64 of the line 63 supplying the first cabin 13 clean, from a three-way valve 76 by heat transfer liquid also taken from the first loop 31 for thermal regulation with single-phase heat transfer liquid. The three-way valve 76 is controlled by the thermal management automation, and has a first inlet connected to the first node 66 for hot withdrawal of the loop 31 and a second inlet connected to the second node 67 for cold withdrawal, allowing the liquid to be drawn coolant either at relatively high temperature or at relatively low temperature.
    The three-way valve 76 has an outlet connected to the inlet of the second circuit of the individual exchanger 75. The output of this second circuit is connected to node 72 of the first thermal regulation loop 31 to recycle the heat transfer liquid in this loop.
    A temperature sensor 77 makes it possible to measure the temperature of the air at the inlet of the second cabin 14 and a temperature sensor 78 makes it possible to measure the interior temperature of the second cabin 14. The thermal management automation controls in particular the three-way valve 76 as a function of the temperature of the air in the mixing chamber 12 measured by the sensor 30, of the different temperature measurements delivered by the different temperature sensors and of a set temperature adjusted by the crew of the aircraft 11, for example from a thermostat specific to the second cabin 14.
    A third cabin 15 which is for example also a passenger cabin is connected to the mixing chamber 12 by a pipe 85 for supplying air clean to this cabin 15 via a first circuit of a heat exchanger air / liquid, said individual exchanger 86. The individual exchanger 86 has a second circuit supplied from a three-way valve 87 with heat transfer liquid taken either from the first loop 31 of thermal regulation with single-phase heat transfer liquid, or from the second loop 51 of thermal regulation with heat transfer liquid monophasic. The three-way valve 87 is controlled by the thermal management automation, and has a first inlet connected to the first node 66 for hot withdrawal of the first loop 31 downstream of the heat exchanger 35 for withdrawing the heat transfer liquid. at a relatively high temperature. The three-way valve 87 has a second inlet connected to a second node 88 for cold withdrawal of the second loop 51 upstream of the heat exchanger 55 for removing the heat transfer liquid at a relatively low temperature. Thus, the second circuit of the individual exchanger 86 is sometimes supplied with liquid at high temperature from the first loop 31 and sometimes by liquid at low temperature by the second loop 51. In fact, this second loop 51 has higher cooling capacities, which can be used in a greater number of individual exchangers than the first loop 31 to adjust the temperature of each cabin of the aircraft 11 in cooling mode.
    The three-way valve 87 has an output connected to the input of the second circuit of the individual exchanger 64. The output of this second circuit is connected by a three-way outlet valve 89 either to node 72 of the first thermal regulation loop 31 to recycle the heat transfer liquid in this loop 31, or to a node 90 of the second regulation loop 51 thermal to recycle the heat transfer liquid in this loop 51. The thermal management automation controls the outlet valve 89 three ways to recycle the heat transfer liquid in the first heat regulation loop 31 when the latter is withdrawn from this first loop
    31, and in the second thermal regulation loop 51 when the heat transfer liquid is taken from this second loop 51. A temperature sensor 91 makes it possible to measure the temperature of the heat transfer liquid at the second node 88 for taking off from the second loop 51. A temperature sensor 92 makes it possible to measure the temperature at node 90 of the second loop 51 to which the three-way outlet valve 89 is connected. A temperature sensor 93 makes it possible to measure the temperature of the air entering the third cabin 15 and a temperature sensor 94 makes it possible to measure the interior temperature of the third cabin 15.
    The thermal management automation controls in particular the three-way vans 87, 89 as a function of the temperature of the air in the mixing chamber 12 measured by the sensor 30, of the different temperature measurements delivered by the different temperature sensors and a set temperature adjusted by the crew of the aircraft 11, for example from a thermostat specific to the third cabin 15.
    A fourth cabin 16, which is for example a hold of the aircraft 11, is directly connected to the mixing chamber 12 by a pipe 96 for supplying air clean to this cabin 16, so as to be supplied with air at the temperature of the air leaving the mixing chamber 12. This air supply pipe 96 is therefore free of air / liquid exchanger, the temperature of the air supplied to the fourth cabin 16 not having to be adjusted individually. Preferably, this fourth cabin 16 is the cabin of the aircraft which has the lowest heat input requirements, both in terms of heating and in terms of cooling. A temperature sensor 97 makes it possible to measure the temperature of the air at the entrance to the fourth cabin 16. A temperature sensor 98 makes it possible to measure the temperature inside the fourth cabin 16. Thus, the automation of management can control the devices 19, 20 for supplying air to the mixing chamber 12 at a controlled temperature only as a function of the heat input requirements of this fourth cabin 16, optimally with respect to the energy consumption of these air supply devices 19, 20. The management automation can thus be adapted to control the temperature inside the mixing chamber 12 to a set temperature in this fourth cabin 16 adjusted by the crew of the aircraft 11, for example from a thermostat specific to the fourth cabin 16.
    A fifth cabin 17, which is for example a passenger cabin, is connected to the mixing chamber 12 by a pipe 107 for supplying clean air to this cabin 17 via a first circuit of a heat exchanger. air / liquid heat, said individual exchanger 108. The individual exchanger 108 has a second circuit supplied from a four-way valve 109 by heat transfer liquid withdrawn from the second heat regulation loop 51 with single-phase heat transfer liquid. The four-way valve 109 is controlled by the thermal management automation, and has a first inlet connected to a first node 110 for hot withdrawal of the second loop 51 downstream of the cooling exchanger 55 for withdrawing the liquid. coolant at a relatively high temperature. The four-way valve 109 has a second inlet connected to the second node 88 for cold withdrawal of the second loop 51 upstream of the heat exchanger 55 for withdrawing the heat transfer liquid at a relatively low temperature. The four-way valve 109 has a third inlet connected to a third node 111 for sampling at intermediate temperature of the second loop 51 between the evaporator 57 and the recirculation exchanger 52 making it possible to sample the heat-transfer liquid at a temperature intermediate between that of the first node 110 and that of second node 88.
    The four-way valve 109 has an output connected to the input of the second circuit of the individual exchanger 108. The output of this second circuit is connected to node 90 of the second thermal regulation loop 51 to recycle the heat transfer liquid in this loop 51.
    A temperature sensor 112 makes it possible to measure the temperature of the air at the entrance to the fifth cabin 17 and a temperature sensor 113 makes it possible to measure the interior temperature of the fifth cabin 17. The thermal management automation controls in particular the four-way valve 109 as a function of the temperature of the air in the mixing chamber 12 measured by the sensor 30, of the different temperature measurements delivered by the different temperature sensors and of a set temperature adjusted by the crew of the aircraft 11, for example from a thermostat specific to the fifth cabin 17.
    A sixth cabin 18, which is for example a passenger cabin, is connected to the mixing chamber 12 by a pipe 118 for supplying clean air to this cabin 18 via a first circuit of a heat exchanger. air / liquid heat, said individual exchanger 119. The individual exchanger 119 has a second circuit supplied from a four-way valve 120 by heat transfer liquid withdrawn from the second heat regulation loop 51 with single-phase heat transfer liquid. This four-way valve 120 is controlled by the management automation and is connected to the second thermal regulation loop 51 like the four-way valve 109 supplying the individual exchanger 108 of the fifth cabin 17.
    A temperature sensor 121 makes it possible to measure the temperature of the air at the inlet of the sixth cabin 18 and a temperature sensor 122 makes it possible to measure the interior temperature of the sixth cabin 18. The thermal management automation controls in particular the four-way valve 120 as a function of the temperature of the air in the mixing chamber 12 measured by the sensor 30, of the different temperature measurements delivered by the different temperature sensors and of a set temperature adjusted by the crew of the aircraft 11, for example from a thermostat specific to the sixth cabin 18.
    Each individual exchanger is chosen in particular according to the nature of the heat transfer fluid supplying the second circuit of this individual exchanger. It can be an air / air exchanger as described for example by US3601185 or other; or of an air / liquid exchanger as described for example by EP 0440400 or US4327802 or the like.
    An example of certain specific steps of a thermal control method according to the invention implemented by an automatic thermal management of a thermal control device according to the invention is shown in Figures 2 and 3. The general characteristics not specific to the invention of a thermal control method and an automatic thermal management system for cabs of a vehicle well known in themselves are not described in detail.
    FIG. 2 represents in particular an example of logic for controlling the devices 19, 20 for supplying air to the mixing chamber which can be implemented in a method according to the invention.
    It is assumed that the vehicle comprises a number N of cabins represented in the following and in Figures 2 and 3 by the index i.
    During step 201, for the different cabins i, that is to say for i = 1, ..., N, a temperature error Δθί between a set temperature Oci for this cabin and a measured temperature Omi for this cabin is calculated. The setpoint temperature Oci can be a setpoint temperature inside the cabin, adjusted by a user by action on a setpoint adjustment command, or a calculated setpoint temperature, for example a calculated setpoint temperature of l air supplying the cabin, itself calculated as a function of the temperature measured in the cabin, the set temperature inside the cabin adjusted by a user, and possibly other parameters. Similarly, the measured temperature Omi can be the temperature measured inside the cabin, or a measured temperature of the air supplying the cabin.
    During step 202, the minimum value MinJAOil on the various booths i of the absolute value of this temperature error is determined.
    Depending on this minimum value, a set temperature 0cx of the air in the mixing chamber (or at the outlet of the latter) can be determined during step 203 according to a temperature control law such that a PID law (proportional, integral, derived).
    From this setpoint temperature 0cx of the air in the mixing chamber and the measured temperature Omx of the air in the mixing chamber (or at its outlet), the operation of each device 19, 20 air supply is controlled during step 204, and in a manner known per se, in particular for delivering an air flow QFj at a temperature 0Fj, j being the index representing the various air supply devices (being equal to 1 or 2 in the example shown in Figure 1).
    FIG. 3 represents an example of control logic for a three-way valve in a method according to the invention for the individual temperature adjustment of the supply air of a cabin i.
    The temperature error Δθί determined during step 201 is compared to the zero value during two tests 301 and 302 (which can of course be combined into a single logic test). At the end of the first test 301, it is determined whether Δθί> 0. If this is the case, this means that the cabin i must be cooled. It is then examined during a subsequent test 303 whether the difference AOlf - 0LF-0mx between the temperature 0LF of the coolant at the cold sampling node connected to the valve and the measured temperature 0mx of the air coming from the mixing chamber is, in absolute value, or not greater than a predetermined threshold value Ds, for example of the order of 5 ° C, ie IAOlfI> Ds. If this is the case, the inlet of the valve connected to this cold sampling node is open during step 304, so that the valve supplies the second circuit of the individual exchanger of cabin i by a flow rate QVli cold coolant. If this is not the case, the valve is closed during step 305, the flow rate QVi delivered by this valve being zero, the temperature of the cabin i not being adjusted individually.
    If test 301 determines that the condition Δθί> 0 is not satisfied, it is determined during a second test 302 if Δθί <0. If this condition is satisfied, this means that cabin i should be warmed up. It is then examined during a subsequent test 306 if the difference AOlc - 0LC-0mx between the temperature 0LC of the coolant at the hot sampling node connected to the valve and the measured temperature 0mx of the air coming from the mixing chamber is, in absolute value, or not greater than a predetermined threshold value Ds, for example of the order of 5 ° C, ie ΙΔΘίχζΙ> Ds. If this is the case, the inlet of the valve connected to this hot sampling node is open during step 307, so that the valve supplies the second circuit of the individual exchanger of cabin i by a flow QV2i hot heat transfer liquid. If this is not the case, the valve is closed during step 305, the flow rate QVi delivered by this valve being zero, the temperature of the cabin i not being adjusted individually.
    If test 302 determines that the condition Δθί <0 is also not satisfied, the valve is closed during step 305, the flow rate QVi delivered by this valve being zero, the temperature of the cabin i not being individually adjusted.
    In particular, in a method according to the invention, the second circuit of an individual exchanger 64, 75, 86, 108, 119 is supplied with a heat-transfer liquid if and only if the temperature of this heat-transfer liquid has a difference compared to the temperature of the air circulating in the first circuit of the individual exchanger 64, 75, 86, 108, 119, that is to say of the air leaving the mixing chamber 12, which is higher, in absolute value, at a predetermined threshold value Ds, which is preferably greater than 1 ° C, for example between 2 ° C and 10 ° C, in particular of the order of 5 ° C. If this condition is not respected, the second circuit of the individual exchanger is not supplied, and the temperature of the air supplying the corresponding cabin is not adjusted individually.
    The invention can be the subject of numerous variant embodiments with respect to the examples represented and described above. The nature, the number of thermal regulation loops with single-phase heat transfer liquid and the way of connecting at least one of these loops to heat exchangers for individual temperature adjustment in each cabin can be the subject of all variants. . Furthermore, nothing prevents the provision of several individual heat exchangers interposed (in parallel or in series) on the same supply line specific to a cabin. Nothing also prevents the provision of several supply lines free of individual exchanger, or on the contrary that all the supply lines of the different cabins are provided with at least one such individual exchanger. The logic for controlling the supply of each second circuit of each individual exchanger can be subject to any suitable variant.
    The invention advantageously applies to the thermal control of the cabins of an aircraft such as an airliner. However, it also applies to all other vehicles in which the same problem arises, for example trains, ships ... A vehicle according to the invention can be fitted with a single thermal control device according to the invention or on the contrary of several thermal control devices in accordance with the invention.
    权利要求:
    Claims (13)
    [1" id="c-fr-0001]
    1 / - Method for thermal control of a plurality of cabins (13 to 18) of a vehicle from a mixing chamber (12) supplied with air from at least one device (19, 20) d air supply of which at least the temperature is controlled, each cabin being supplied with air:
    - from the mixing chamber (12),
    - by a supply line (63, 74, 85, 96, 107, 118) specific to this cabin,
    - independently of each other cabin, characterized in that:
    - at least one cabin (13, 14, 15, 17, 18) is supplied with air at a temperature adjusted by at least one individual heat exchanger, said exchanger (64, 75, 86, 108, 119), associated with said supply line (63, 74, 85, 96, 107, 118) specific to this cabin,
    - Air from the mixing chamber (12) passing through a first circuit of each individual exchanger (64, 75, 86, 108, 119) associated with said pipe (63, 74, 85, 96, 107, 118 ) supplying power specific to a cabin and independently supplying said cabin (13, 14, 15, 17, 18), this first circuit being interposed between said cabin (13, 14, 15, 17, 18) and the mixing chamber ( 12) on said supply line (63, 74, 85, 96, 107, 118) specific to said cabin,
    - at least a second circuit of at least one individual exchanger (64, 75, 86, 108, 119) associated with a supply line specific to a cabin is supplied with a heat transfer fluid coming from at least one loop ( 31, 51) for thermal regulation of the vehicle,
    - this heat transfer fluid being selected:
    o among:
    at least one heat transfer fluid taken from a thermal regulation loop of the vehicle at a temperature higher than the temperature of the air coming from the mixing chamber (12), at least one heat transfer fluid taken from a thermal regulation loop of the vehicle at a temperature below the temperature of the air coming from the mixing chamber (12), o so that each individual exchanger (64, 75, 86, 108, 119) associated with the supply line specific to said cabin individually adjusts the temperature of the air supplying said cabin according to a set temperature for said cabin.
    [2" id="c-fr-0002]
    2 / - Method according to claim 1 characterized in that said heat transfer fluid is selected from:
    10 - at least one heat transfer fluid taken from a thermal regulation loop of the vehicle at a temperature higher than the temperature of the air coming from the mixing chamber (12), when said set temperature is higher than the temperature of l air from the mixing chamber (12),
    - at least one heat transfer fluid taken from a regulation loop
    15 thermal of the vehicle at a temperature below the temperature of the air from the mixing chamber (12), when said set temperature is lower than the temperature of the air from the mixing chamber (12) .
    [3" id="c-fr-0003]
    3 / - Method according to claim 2 characterized in that the heat transfer fluid is selected so that each exchanger (64, 75, 86, 108, 119)
    20 individually associated with the supply line specific to said cabin individually adjusts the temperature of the air supplying said cabin as a function of a set temperature which is a set temperature of the air supplying said cabin (13, 14, 15, 17, 18).
    [4" id="c-fr-0004]
    4 / - Method according to one of claims 1 to 3 characterized
    25 in that said selected heat transfer fluid is a single-phase heat transfer fluid taken from a loop (31, 51) for thermal regulation.
    [5" id="c-fr-0005]
    5 / - Method according to one of claims 1 to 4 characterized in that said selected heat transfer fluid is taken from a loop (31, 51) of thermal regulation with single-phase heat transfer liquid for cooling electronic equipment of the vehicle.
    [6" id="c-fr-0006]
    6 / - Method according to one of claims 1 to 5 characterized in that each second circuit is supplied with heat transfer fluid by means of a multi-way valve (65, 76, 87, 109, 120) having an outlet connected to the second circuit, a first input connected to a first heat transfer fluid sample from a loop (31, 51) for thermal regulation of the vehicle and at least a second input connected to a second heat transfer fluid sample from a loop (31, 51 ) thermal regulation of the vehicle, the second sample being adapted to be able to deliver heat transfer fluid at a temperature different from the temperature of the heat transfer fluid that can be delivered by the first sample.
    [7" id="c-fr-0007]
    7 / - A method according to claim 6 characterized in that each second circuit is supplied with heat transfer fluid by means of a three-way valve (65, 76, 87) having two inputs connected to two separate samples of heat transfer fluid at separate temperatures, and an output connected to one or other of its two inputs.
    [8" id="c-fr-0008]
    8 / - Device for thermal control of a plurality of cabins (13 to 18) of a vehicle comprising:
    - a mixing chamber (12),
    - at least one device (19, 20) for supplying air connected to the mixing chamber (12) for supplying it with air at controlled temperature,
    - a thermal management automation adapted to control at least the temperature of the air supplied by each device (19, 20) supplying air to the mixing chamber (12) as a function of at least one set temperature d '' at least one cabin of the vehicle,
    - each cabin (13 to 18) being connected to the mixing chamber (12) by a supply line specific to this cabin so as to be able to be supplied with air from the mixing chamber independently of each other cabin, characterized in that :
    - at least one heat exchanger, said exchanger (64, 75, 86, 108, 119) individual, is associated with at least one supply line (63, 74, 85, 96, 107, 118) specific to a cabin (13, 14, 15, 17, 18),
    - each individual exchanger (64, 75, 86, 108, 119) includes:
    5 o a first interposed circuit, between said cabin (13, 14, 15, 17, 18) and the mixing chamber (12), on said clean supply line (63, 74, 85, 96, 107, 118) to said cabin so that it can be traversed by air coming from the mixing chamber (12) and supply said cabin (13, 14, 15, 17, 18),
    10 o a second circuit connected to at least one loop (31, 51) for thermal regulation of the vehicle's heat transfer fluid in order to be able to be supplied by this heat transfer fluid,
    - said thermal management automation is adapted to supply at least a second circuit of at least one associated exchanger (64, 75, 86, 108, 119)
    15 to a supply line specific to a cabin by a heat transfer fluid coming from at least one loop (31, 51) of thermal regulation of the vehicle,
    - said thermal management automation is suitable for selecting this heat transfer fluid:
    o among:
    20 at least one heat transfer fluid taken from a thermal regulation loop of the vehicle at a temperature higher than the temperature of the air coming from the mixing chamber (12), at least one heat transfer fluid taken from a thermal regulation loop of the vehicle at a temperature below the
    25 temperature of the air coming from the mixing chamber (12), o chosen so that each individual exchanger (64, 75, 86, 108, 119) associated with the supply line specific to said cabin individually adjusts the temperature air supplying said cabin as a function of a set temperature for said cabin.
    [9" id="c-fr-0009]
    9 / - Device according to claim 8 characterized in that each second circuit is connected to at least one loop (31, 51) for thermal regulation of the vehicle via a valve (65, 76, 87, 109, 120 ) multi-channel having an output connected to the second circuit, a first input connected to a first heat transfer fluid sample from a vehicle thermal regulation loop and at least one second input connected to a second heat transfer fluid sample from a regulation loop thermal of the vehicle, the second sample being adapted to be able to deliver heat transfer fluid at a temperature different from the temperature of the heat transfer fluid that can be delivered by the first sample.
    [10" id="c-fr-0010]
    10 / - Device according to claim 9 characterized in that the first sample and each second sample are separate samples of the same loop (31, 51) of thermal regulation of the vehicle.
    [11" id="c-fr-0011]
    11 / - Device according to one of claims 8 to 10 characterized in that at least one loop (31, 51) for thermal regulation of the vehicle connected to at least a second circuit is a thermal regulation loop with single-phase heat transfer fluid.
    [12" id="c-fr-0012]
    12 / - Device according to one of claims 8 to 11 characterized in that at least one loop (31, 51) of thermal regulation of the vehicle connected to at least a second circuit is a thermal regulation loop with single-phase heat transfer liquid of cooling of on-board vehicle equipment.
    [13" id="c-fr-0013]
    13 / - Vehicle - in particular aircraft - comprising at least a plurality of cabins (13 to 18), at least one device for thermal control of each plurality of cabins and at least one loop (31, 51) for thermal regulation with heat transfer fluid, characterized in that it comprises at least one thermal control device according to one of claims 8 to 12.
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    类似技术:
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    同族专利:
    公开号 | 公开日
    US20180305030A1|2018-10-25|
    EP3392146A1|2018-10-24|
    US10752365B2|2020-08-25|
    FR3065518B1|2019-07-05|
    EP3392146B1|2019-11-06|
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    法律状态:
    2018-04-26| PLFP| Fee payment|Year of fee payment: 2 |
    2018-10-26| PLSC| Publication of the preliminary search report|Effective date: 20181026 |
    2019-06-25| PLFP| Fee payment|Year of fee payment: 3 |
    2020-04-20| PLFP| Fee payment|Year of fee payment: 4 |
    2021-04-24| PLFP| Fee payment|Year of fee payment: 5 |
    优先权:
    申请号 | 申请日 | 专利标题
    FR1753435|2017-04-20|
    FR1753435A|FR3065518B1|2017-04-20|2017-04-20|METHOD AND DEVICE FOR THERMALLY CONTROLLING A PLURALITY OF CABINS OF A VEHICLE|FR1753435A| FR3065518B1|2017-04-20|2017-04-20|METHOD AND DEVICE FOR THERMALLY CONTROLLING A PLURALITY OF CABINS OF A VEHICLE|
    US15/951,200| US10752365B2|2017-04-20|2018-04-12|Method and device for thermal control of a plurality of cabins of a vehicle|
    EP18167305.4A| EP3392146B1|2017-04-20|2018-04-13|Method and device for thermal control of a plurality of cabins of a vehicle|
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