FR2976322A1 - Air distributor for combustion engine of heat transfer system in car, has two U-shaped heat exchangers connected in series with respect to charging air and traversed by coolant having specified temperature at inlets of exchangers - Google Patents

Abstract

The distributor (1) has a device adapted to exchange heat with charging air (2) for a combustion engine. U-shaped heat exchangers (5, 6) are connected in series with respect to charging air and traversed by a coolant, where the coolant has specified temperature at inlets of the heat exchangers. Delimitation walls (7) form an external structure. The heat exchangers are fixed at the external structure in a watertight way to correctly guide the charging air. A bypass pipe (9) is arranged parallel to one of the exchangers and series with the other exchanger. An independent claim is also included for a heat transfer system.

Description

The invention relates to an air distributor and a device for exchanging heat with supercharger air, and a heat transfer system comprising such a distributor. heat disposed in such an air distributor, and a heat transfer system comprising such a distributor. [0002] It is conventional to have, on the air intake line of the combustion engine of a motor vehicle, a compressor which is intended to compress the air before it is admitted to the combustion chambers of the engine. compressor shaft being connected to that of a turbine which is driven by the combustion gases at the output of the engine. In order to maintain the density of the air acquired at the outlet of the compressor, the air having a tendency to expand at the outlet of the compressor, it is usual to arrange, between the compressor and the engine, a heat exchange device which is intended to cool the compressed air. [0003] In order to promote energy savings and to reduce carbon dioxide emissions and pollutants, motor vehicles tend to be equipped with combustion engines whose capacity is increasingly low but whose performance is maximum, torque at low speed, brio) are at least identical if not superior to the combustion engines replaced. This trend also leads to the general use of supercharged air (particularly by means of a turbocharger) requiring a significant cooling performance. Thus, to meet the performance and clean-up requirements of the combustion engine and architectural compactness, it is increasingly necessary to further cool the charge air. It has therefore become conventional that the heat exchange device uses a coolant circulating in a loop which also comprises an auxiliary heat exchanger (typically a radiator) intended to cool, by the air coming from the outside of the vehicle, the coolant which has been heated by the charge air in the heat exchange device. [0004] In order to improve the cooling performance, in certain vehicles the heat exchange device comprises two heat exchangers which are connected in series with respect to the charge air, each heat exchanger being traversed by a heat exchanger. coolant having a temperature of its own at the inlet of the corresponding exchanger. Conventionally, one of the heat transfer liquids is the engine coolant which allows to significantly lower the charge air (the latter can exit the compressor at temperatures between 180 ° C and 200 ° C, or at the other liquid (which has been cooled more than the engine coolant by an auxiliary heat exchanger such as a radiator) makes it possible to complete the cooling of the charge air. However, such combustion engines of very high specific power and supercharged to the extreme have requirements in break of their supercharging system, including cooling. Such needs require a very efficient supercharging air cooling circuit, particularly with regard to the performance of the water pump and the heat exchangers (surface, thickness and intrinsic performance of the heat exchangers involved in the cooling of the heat exchanger. air of overeating) that go against the mass objectives, costs and space allocated to such adaptations. On the other hand, even if under most driving conditions the air must be as fresh as possible at the engine inlet to improve the filling of the engine, the evolution of the standards of depollution may require the hot air under certain driving conditions. This is particularly the case when it is necessary to regenerate a particulate filter or when starting the cold engine that generates too much carbon monoxide and unburned hydrocarbons. Finally, the currently used architectures have the disadvantage of being able to generate, under certain operating conditions of the engine and the vehicle and under certain climatic conditions (hygrometry, outside temperature ...), the deposition of condensates which, in particular by fouling, accumulation or gel, can degrade the operation of the engine. This generates constraints (costs, front overhang, access for repairs ...) to install in the front of the vehicle, a heat exchanger sized to evacuate the maximum level of calories on life situations extreme, without impacting the other heat exchangers of the vehicle (radiator for the cooling of the engine, condenser for the air conditioning of the vehicle) nor the functional and the associated services (air conditioning, cooling and supercharging of the engine). The invention aims to solve one or more of these disadvantages. 1. According to a first aspect, the invention relates to an air distributor for a combustion engine comprising a device adapted to exchange heat with charge air for the combustion engine, the device comprising two heat exchangers. heat mounted in series vis-à-vis the charge air, each heat exchanger being traversed by a coolant which, at the inlet of the exchanger, has a temperature of its own. [000si Thus, by housing the two heat exchangers in the air distributor which distributes the air from the compressor in the different combustion chambers of the engine, the number of areas of the engine compartment of the vehicle can be dangerous during a shock is not increased so far, the air distributor is in itself a potentially traumatic element. In addition, the pressure losses of the charge air circuit are greatly reduced (of the order of 50 to 80%), generating significant gains in performance of the combustion engine. Similarly, the response time of the engine benefits from the reduction (20 to 35%) of the volume of air between the output of the turbocharger and the engine inlet, through the drastic reduction of the lengths of the air ducts and the smaller size of the charge air cooler, resulting in a gain in transient engine behavior. [0010] A two-stage cooling of the charge air thus makes it possible to reduce the size of the low-temperature heat-transfer circuit, by allowing the use of a standard performance water pump of reduced size, thus less expensive, and without require surfaces and / or heat exchanger performance too bulky and / or expensive. This makes it possible to make the supercharging air thermo-management system very compact while optimizing the passage section offered to the supercharging air and the length of the successive paths of the air within the heat exchangers in order to optimize the aeraulic pressure drop of the system. The specific power of the combustion engine can be increased by an increased cooling of the charge air or for the same specific power, the size of the combustion engine and its adaptation components can be reduced, leading to an improvement in the installation in the engine compartment of the vehicle. In addition, the reduction of the volume of air between the outlet of the compressor and the air intake into the combustion chamber and the increased thermal inertia of the air intake system, with in particular a better system efficiency at low vehicle speeds, allows a significant gain in brio of the engine.

Such a device improves the homogeneity of the temperature of the air admitted into the cylinders and thus improves the rattling behavior: it follows a way of optimizing the ignition to improve the fuel consumption. The two heat exchangers can be separated from one another by a partition wall forcing the supercharging air through the upstream heat exchanger before passing through the downstream heat exchanger. In this way, the charge air is forced through the two heat exchangers, which allows optimization of air cooling and homogenization of the air temperature at the inlet of the different combustion chambers. This partition wall is advantageously adapted to thermally isolate each exchanger from each other. The absence of a thermal bridge between the two heat exchangers makes it possible to improve the cooling efficiency of the charge air by the low-temperature coolant. According to a second aspect, the invention relates to an air distributor for a combustion engine, characterized in that it comprises a device adapted to exchange heat with supercharging air according to the first aspect of the present invention. According to a first embodiment of the second aspect of the invention, the air distributor comprises delimiting walls forming its external structure, and to which the heat exchangers are sealed so as to guide the air correctly. of overeating. According to a variant of this first embodiment, the boundary walls are adapted to thermally insulate the elements located inside these air walls of the engine compartment and the combustion engine. According to a second embodiment of the second aspect of the invention, at least one of the two heat exchangers is a U-shaped heat exchanger. As a result, the inlet and the outlet of the heat transfer fluid passing through the U-shaped heat exchanger are arranged on the same side of the exchanger, which facilitates the establishment of the latter in the distributor (insertion by translation) and access for possible subsequent operations. This characteristic also makes it possible to optimize the implementation of the different levels of sealing, on the one hand between the walls of the air distributor and the exchangers, and on the other hand to the outside. According to a variant of this second embodiment, the two heat exchangers are U. According to a third embodiment of the second aspect of the invention, the two heat exchangers and the partition wall between the two exchangers are arranged so that the air passing through the two exchangers successively makes a U-shaped path, the upstream exchanger being traversed in one direction, and the downstream exchanger in the opposite direction. This U-shaped arrangement of the charge air circuit makes it possible to reduce the size of the distributor and to facilitate access to the two heat exchangers. According to a fourth embodiment of the second aspect of the invention, the air distributor comprises a bypass line arranged to be in parallel with a first heat exchanger and in series with a second heat exchanger. Therefore, it is possible, depending on the needs, to adapt the heat exchange with the charge air by allowing or preventing the supercharging air to pass through one of the heat exchangers. According to an advantageous variant of the fourth embodiment, the bypass line is in parallel with the upstream exchanger and in series with the downstream heat exchanger. According to a preferred embodiment of the advantageous variant, the bypass line is separated from the upstream heat exchanger by a partition wall which is adapted to thermally isolate the bypass line of the upstream heat exchanger. According to a fifth embodiment of the second aspect of the invention, the air distributor comprises a short-circuit passage arranged to allow the air to short circuit the two exchangers. Therefore, it is possible, depending on the needs, to adapt the heat exchange with the charge air by allowing or preventing the supercharging air to pass through the two heat exchangers. According to a sixth embodiment of the second aspect of the invention, the air distributor comprises, at its air inlet, a multi-position distribution valve adapted to impose air its circulation in the distributor . Such an arrangement makes it possible not only to cool the charge air but also to heat it, as required. Heating the air accelerates the temperature rise of the combustion engine, generating a gain in fuel consumption, a reduction in the source of polluting emissions and a significantly faster achievement of thermal comfort in the passenger compartment of the vehicle by cold outdoor conditions. It also makes it possible to inhibit the regeneration abortions of a particulate filter installed on the exhaust line of the combustion gases and the condensate gel inside the charge air cooler of the combustion engine. According to a first variant of this sixth embodiment, the distribution valve is adapted to take a maximum thermal transfer position in which the supercharging air is sent in a circuit comprising upstream downstream, a conduct in which is disposed the upstream exchanger and a pipe in which is disposed the downstream heat exchanger. According to a second variant of this sixth embodiment, the distribution valve is adapted to take a partial heat transfer position in which the supercharging air is sent in a circuit comprising upstream downstream, the driving of derivation and a pipe in which is disposed the downstream heat exchanger. According to a third variant of this sixth embodiment, the dispensing valve is adapted to take a short-circuit position in which the air is sent in a circuit comprising only the short-circuit passage. According to a third aspect, the invention relates to a heat transfer system comprising a combustion engine, the heat transfer system being adapted to allow cooling of the charge air before admission to the engine, characterized in that it comprises an air distributor arranged at the engine inlet and according to the second aspect of the present invention. According to a first embodiment of the third aspect of the invention, the heat transfer system comprises a control system adapted to control the position of the dispensing valve as a function of the temperature of the charge air and the engine speed and load. According to a second embodiment of the third aspect of the invention, the coolant passing through the heat exchanger disposed upstream in the distributor is the engine coolant. This allows a space saving and a simplification of the coolant circuit circulating in the upstream exchanger, given the natural proximity of the air distributor and the engine, the coolant being advantageously derived from an internal cooling tube to the engine. According to a third embodiment of the third aspect of the invention, the heat transfer system is associated with a high pressure exhaust gas recirculation circuit adapted to introduce the recirculation gas into the air distributor. This makes it possible to have very efficient cooling of the recirculating exhaust gas and thus a reduction of the nitrogen oxides emitted by the vehicle. According to a first variant of the second embodiment of the third aspect of the invention, the control system is arranged to control the position of the dispensing valve in the maximum thermal transfer position and to allow the circulation of liquids. coolers in each of the two heat exchangers when the engine is fully loaded and the charge air temperature at the inlet of the air distributor is greater than that of the engine coolant at the inlet of the engine. upstream heat exchanger. Advantageously, in this first variant in connection with the third embodiment of the third aspect, when the control system controls the position of the dispensing valve in maximum heat transfer position and allows the circulation of heat transfer liquids in each of the two heat exchangers, the control system blocks the recirculation of gases. According to a second variant of the second embodiment of the third aspect of the invention, the control system is arranged to control the position of the dispensing valve in the partial heat transfer position and to allow the circulation of the liquid. coolant in the downstream heat exchanger when the engine is under partial load and the charge air temperature at the inlet of the air distributor is lower than that of the engine coolant at the inlet of the engine. heat exchanger upstream and above that of the low temperature coolant at the inlet of the downstream heat exchanger. Advantageously, in this second variant in connection with the third embodiment of the third aspect, when the control system controls the position of the dispensing valve in the partial heat transfer position and allows the circulation of coolant liquid low temperature in the downstream heat exchanger, the control system also allows the circulation of recirculating gases. According to a third variant of the second embodiment of the third aspect of the invention, the control system of the dispensing valve is arranged to control the position of the dispensing valve in the short-circuit position when, cumulatively, on the one hand, the engine is in the warm-up phase, and, on the other hand, either the engine does not need to be supplied with heated air, that is the temperature of the engine coolant at the engine. inlet of the upstream heat exchanger does not heat up the charge air.

The charge air then passes through neither of the two upstream and downstream heat exchangers and is therefore directed towards the intake pipes and combustion chambers of the engine.  According to a fourth variant of the second embodiment of the third aspect of the invention, the control system is arranged to control the position of the dispensing valve in the maximum thermal transfer position and to block the circulation of the liquid. coolant in the downstream heat exchanger when the engine requires a heated air supply.  According to a fifth variant of the second embodiment of the third aspect of the invention, the engine coolant circuit comprises a distributor loop which comprises the upstream heat exchanger of the air distributor and whose inlet is disposed downstream of the junction of the cooling leg and a bypass branch, the cooling branch comprising a high temperature radiator adapted to cool the coolant exiting the engine, and the bypass branch bypassing this radiator.  According to a first version of this fifth variant, the input of the distributor loop is arranged upstream of a pump adapted to circulate the engine coolant 10.  According to a second version of this fifth variant, the input of the distributor loop is disposed upstream of the output of a heater loop in which the coolant output of the engine passes through a heater.  Such a heater allows to heat air coming from outside or recirculation 15 penetrating the passenger compartment of the motor vehicle.  According to a fourth embodiment of the third aspect of the present invention, the heat transfer system comprises a low temperature heat transfer liquid circuit in which the low temperature heat transfer liquid cyclically passes through the downstream heat exchanger of the air distributor. and a low temperature radiator 20 for cooling.  According to a first variant of the fourth embodiment of the third aspect of the invention, the low temperature heat transfer liquid circuit comprises a pump adapted to circulate the low temperature heat transfer liquid.  [0044] According to a second variant of the fourth embodiment of the third aspect of the invention, the heat transfer system comprises a suitable coupling valve, in the open position, to allow the circulation of the low temperature heat transfer liquid through the radiator. high temperature if and only if a bypass valve adapted to distribute the engine coolant between the cooling branch and the branch branch closes the access to the cooling branch.  According to a particular embodiment of this second variant, in the open position, the coupling valve allows the paralleling of the high temperature radiator with the low temperature radiator.  According to a third variant of the fourth embodiment of the third aspect of the invention, the low temperature heat transfer liquid circuit is a low temperature branch of the engine coolant circuit, the low temperature radiator being upstream of the engine. heat exchanger downstream of the air distributor.  According to a first feature of this third variant, the low temperature branch of the engine coolant circuit is a bypass loop whose input is downstream of the high temperature radiator and upstream of the junction between the branch of the engine coolant circuit. cooling and branch branch.  According to a second feature of this third variant, the low temperature branch of the coolant circuit is a bypass loop whose input is in the heater loop.  According to a fourth variant of the fourth embodiment, the motorization system comprises a single degassing box fed by the high temperature radiator.  Other features and advantages of the invention will become apparent from the description which is given below, by way of indication and in no way limiting, with reference to the accompanying drawings, in which: FIG. 1 illustrates a splitter box; air intake taken in a section in the direction of flow of the charge air, the dispensing valve being in its maximum thermal transfer position and the high and low temperature heat transfer liquids circulating respectively in the two upstream heat exchangers and downstream; FIG. 2 illustrates the air distributor of FIG. 1, the dispensing valve being in its partial thermal transfer position and the high and low temperature heat transfer liquids flowing respectively in the two upstream and downstream heat exchangers; - Figure 3 illustrates the air distributor of Figures 1 and 2, the dispensing valve being in its short-circuit position; FIG. 4 illustrates the air distributor of FIGS. 1 to 3, the dispensing valve being in its maximum thermal transfer position and the high temperature heat transfer liquid circulating in the upstream heat exchanger only; FIG. 5 illustrates a first embodiment of the circuits of the two high and low temperature heat transfer fluids, the bypass valve for distributing the engine coolant between a cooling branch and a branch branch being in a position where the cooling branch is closed; FIG. 6 illustrates the circuits of the two high and low temperature heat transfer fluids of FIG. 5, the bypass valve being in a position where the bypass branch is closed; FIG. 7 illustrates a second embodiment of the circuits of the two high and low temperature heat transfer fluids, the bypass valve being in a position where the cooling branch is closed, the coupling valve allowing to connect or not the radiator of the liquid. cooling the engine to the low temperature coolant circuit being in the position where the engine coolant radiator is connected to the low temperature coolant circuit; FIG. 8 illustrates the circuits of the two high and low temperature heat transfer liquids of FIG. 7, the bypass valve being in a position where the bypass branch of the engine coolant is closed, and the coupling valve being in a position position where the radiator of the engine coolant is in communication with the cooling circuit of the combustion engine and thus isolated from the low temperature heat transfer liquid circuit.  An air distributor 1 for a combustion engine 3 is illustrated in Figures 1 to 4.  This distributor 1 comprises an inlet (through which between the intake air 2 of the engine 3 or, if the vehicle has an exhaust gas recirculation circuit, a mixture of air and recirculation gas) not shown, and an outlet 4 opening into the combustion chambers of the engine 2.  The air distributor 1 comprises a heat exchange device adapted to allow exchange of heat between the air 2 (or the mixture of air and recirculating gas) and heat transfer liquids.  More specifically, the heat exchange device comprises two heat exchangers 5, 6 connected in series with respect to the charge air, each heat exchanger 5, 6 being traversed by a heat transfer liquid having a its own temperature at the inlet of the corresponding exchanger.  In order to allow staged cooling, the upstream heat exchanger 5 is traversed by a high temperature heat transfer liquid, and the downstream heat exchanger 6 is traversed by a low temperature heat transfer liquid.  In the present embodiment, the two heat exchangers 5, 6 are arranged so that the air passes through them successively in a U-shaped path, the upstream exchanger 5 being traversed in one direction, and the downstream exchanger 6 in the opposite direction.  This construction reduces the space requirement of the air distributor 1.  Preferably, the two exchangers 5, 6 are arranged one (here, the upstream exchanger 5) above the other (here, the downstream exchanger 6).  Each of the two heat exchangers 5, 6 are conventional air / water heat exchangers with tubes and fins.  In order to improve the heat exchange, preferably, on the one hand, the tubes in which the heat transfer liquids circulate are equipped with devices creating internal turbulence, and, on the other hand, the fins between which the air circulates. are equipped with shutters.  For the same purpose, the fins are preferably brazed to the tubes in order to maximize the thermal contact between them and are arranged so as to maximize the exchange surfaces between the air 2 and the coolant.  In order to facilitate their access, each of the two heat exchangers 5, 6 is of the U-shaped type so that the inlet and the outlet of the coolant are located on the same side of the distributor 1.  In addition, this feature also makes it possible to perform the insertion of the exchangers 5, 6 into the distributor 1 by a translation.  This method also makes it possible to optimize the implementation of the different sealing levels (outwards and between the distributor 1 and the exchangers 5, 6).  The air distributor 1 also comprises delimiting walls 7 forming its external structure to which the heat exchangers 5, 6 are fixed so as to correctly guide the air 2, the internal sealing of the distributor 1, between the exchangers 5, 6 and delimiting walls 7 being particularly neat, especially given the boost pressure levels, in order to force the supercharging air to pass through both exchangers 5, 6 without bypassing them and to promote homogeneity of the temperature of the air 2 introduced into each cylinder of the combustion engine 3.  The delimiting walls 7 are preferably adapted to thermally insulate the internal constituents of the distributor 1 (in particular the heat exchangers 5 and 6 as well as the charge air 2 circulating inside the different parts of the distributor 1) of the air circulating in the engine compartment and the combustion engine 3.  The heat exchange device comprises, in addition to the two heat exchangers 5, 6, a partition wall 8 separating the two heat exchangers 5, 6 from one another.  This separating wall 8 forces all the air 2 entering the distributor 1 to pass through the upstream exchanger 5 before passing through the downstream exchanger 6.  Preferably, the partition wall 8 is adapted to thermally isolate the heat exchangers 5, 6 from each other in order to prevent heating of the heat exchanger in which the low-temperature heat transfer fluid circulates through the heat exchanger. heat exchanger in which circulates the high temperature heat transfer liquid.  As for the exchangers 5, 6, the partition wall 8 is fixed to the delimiting walls 7 in a sealed manner in order to correctly guide the air 2.  And as for fixing the exchangers 5, 6 to the delimiting walls 7, the internal seal of the distributor 1 between the exchangers 5, 6 and the partition wall 8 is particularly neat, for the same reasons of air pressure of supercharging and air temperature homogeneity requirements 2 entering each cylinder of the combustion engine 3.  As illustrated in the drawings, in the present embodiment, the air distributor 1 comprises a bypass line 9 which is arranged to be in parallel with a first exchanger (in this case, the heat exchanger upstream 5) and in series with a second exchanger (in this case, the downstream exchanger 6).  As a result, the air 2 flowing in this bypass line 9 bypasses the upstream exchanger 5, but not the downstream exchanger 6.  To satisfy this embodiment, the air distributor 1 comprises an internal wall 10 which separates the upstream heat exchanger 5 from the bypass pipe 9, the latter thus being above the upstream heat exchanger 5.  Like the partition wall 8, the inner wall 10 forces all the supercharging air 2 passing through the inlet of the bypass pipe 9 to pass through the latter before passing through the downstream heat exchanger 6.  In addition, the inner wall 10 is preferably adapted to thermally insulate the air circulating in the bypass line 9 of the upstream heat exchanger 5 in order to prevent heating of the air circulating in the bypass line 9 by the 5 upstream heat exchanger in which circulates the high temperature heat transfer liquid.  As for the exchangers 5, 6, the inner wall 10 is fixed to the delimiting walls 7 in a sealed manner in order to correctly guide the air 2.  And as for the attachment of the exchangers 5, 6 to the delimiting walls 7 and to the partition wall 8, the internal sealing of the distributor 1 between the exchangers 5, 6 and the inner wall 10 is particularly neat, for the same reasons. supercharging air pressure and air temperature homogeneity requirements 2 entering each cylinder of the combustion engine 3.  The air distributor 1 also comprises a short-circuit passage 11 which is arranged to allow the air 2 entering the distributor 1 to exit directly.  As a result, the air 2 flowing in this short-circuit passage 11 bypasses the upstream exchanger 5 and the downstream exchanger 6.  The air distributor 1 also comprises a distribution valve 12 at several positions for imposing air 2 several circulations in the distributor 1 according to the temperature setpoint of the air 2 at the inlet of the combustion chambers , the speed and the load applied to the combustion engine 3 and the temperatures of the heat transfer liquids.  The distribution valve 12 is disposed after the air inlet of the distributor, downstream of the air metering housing (or throttle housing).  In the present embodiment, in order to optimize, at the outlet of the distributor 1, the homogeneous distribution of the mass of the air 2 and its temperature towards each combustion cylinder, the air metering housing (or the throttle body ) is advantageously arranged on one side of the distributor 1 in order to have an initial lateral air flow.  As illustrated in Figures 1 to 4, the distribution valve 12 is placed at one end of the bypass pipe 9 and the pipe 13 in which is disposed the upstream heat exchanger 5 to be able to supply air to the air. one or other of these two lines 9, 13.  In addition, the distribution valve 12 is arranged so as not to be able to directly supply air 2 to the pipe 14 in which the downstream heat exchanger 6 is disposed.  For this purpose, the air distributor comprises an annex wall 15 between the distribution valve 12 and this duct 14.  Finally, the air distributor 1 comprises a common space 16 disposed where the bypass pipe 9 opens, the pipe 13 in which is disposed the upstream heat exchanger 5 and the pipe 14 in which is disposed the heat exchanger downstream heat 6.  This common space allows the passage of the air 2 coming either from the bypass line 9, or from the pipe 13 in which the upstream heat exchanger 5 is arranged, to flow in the pipe 14 in which the exchanger is arranged. downstream heat 6.  The distribution valve 12 is here adapted to be able to take three different positions for three different air flows 2 in the distributor 1.  Figures 1 and 4 illustrate the dispensing valve 12 in a maximum thermal transfer position in which the air 2 is sent in a circuit comprising upstream downstream, the pipe 13 in which is disposed the heat exchanger upstream heat 5, the common space 16 and the pipe 14 in which the downstream heat exchanger 6 is arranged.  Thus, in this embodiment, the air passes through the two exchangers 5, 6.  FIG. 2 illustrates the distribution valve 12 in a partial heat transfer position in which the air 2 is sent in a circuit comprising from upstream to downstream, the bypass pipe 9, the common space 16 and the pipe 14 in which is disposed the downstream heat exchanger 6.  Thus, in this embodiment, the air passes only through the downstream heat exchanger 6.  Finally, FIG. 3 illustrates the dispensing valve 12 in a short-circuit position in which the air 2 is sent in a circuit comprising only the short-circuit passage 11.  Thus, in this embodiment, the air does not pass through any heat exchanger.  The air distributor 1 is an integral part of a heat transfer system 17, 18 which comprises the combustion engine 3.  This heat transfer system 17, 18 makes it possible in particular to cool or heat the intake air at the outlet of the compressor (not shown).  The heat transfer system 17, 18 also comprises a control system which is adapted to control the temperature of the air 2 at the inlet of the engine 3, the temperature of each coolant, and the position of the distribution valve 12, depending in particular on the temperature, the speed and the load of the engine 3.  Thus, the control system is arranged to control the distribution valve 12 in the maximum thermal transfer position in two types of circumstances.  In the first type of circumstances, the control system also controls the actuators of the heat transfer system so as to allow the circulation of heat transfer liquids in each of the two heat exchangers 5, 6.  This first type of circumstance occurs when the engine 3 is fully loaded.  As a result, the air is strongly compressed and exits at a high temperature (typically up to 180 to 200 ° C. or more), higher than that of the high temperature heat transfer liquid circulating in the upstream heat exchanger 5, and therefore requires a significant cooling down to a value between 30 and 40 ° C (cf.  figure 1).  In such a circumstance, in the case where the heat transfer system 17, 18 is associated with a high-pressure combustion gas recirculation system, the control system also controls the closure of the recirculation line.  In the second type of circumstances, the control system also controls the actuators of the heat transfer system so as to allow the circulation of the only high temperature heat transfer liquid in the upstream heat exchanger 5 and to prevent that of the low temperature heat transfer liquid in the downstream heat exchanger 6.  This second type of circumstance occurs when the engine 3 needs air having a high temperature.  As a result, the upstream exchanger 5 is used, not to cool the air 2, but to heat it, and stopping the circulation of the low-temperature heat-transfer liquid makes it possible to prevent the cooling of the heated air when it passes through the downstream heat exchanger 6 (cf.  Figure 4).  This second type of circumstance corresponds in particular to the temperature increase phases of the engine 3 to admit into the combustion chambers a warmer air favorable to the smooth running of the combustion of the fuel and to the faster priming of the depollution and post-pollution devices. -treatment of the exhaust gas, the regeneration phases of the particulate filter to help increase the temperature of the gas inlet of the particulate filter in the exhaust pipe of the engine 3, and weather conditions and rolling may lead to condensate gel like crankcase gases in the system.  The control system is also arranged to control the distribution valve 12 in the partial heat transfer position when the engine 3 is in partial load and the air temperature 2 at the inlet of the distributor 1 is less than that of the high temperature heat transfer liquid at the inlet of the upstream heat exchanger 5 and greater than that of the low temperature heat transfer liquid at the inlet of the downstream heat exchanger 6 (cf.  Figure 2).  In such circumstances, the control system also controls the actuators of the heat transfer system so as to allow the circulation of heat transfer liquids in each of the two heat exchangers 5, 6 (in any case, at least the circulation of the low heat transfer liquid temperature in the downstream heat exchanger 6).  In the case where the heat transfer system 17, 18 is associated with a high pressure combustion gas recirculation system, the control system also controls, if necessary, the opening or closing of the recirculation pipe.  The control system is finally arranged to control the distribution valve 12 in the short-circuit position in two types of circumstances: either when the engine 3, in the temperature rise phase, does not need to be supplied with air 2 reheated, ie, the engine 3 being in a temperature rise phase, when the temperature of the high temperature heat transfer liquid at the inlet of the upstream exchanger 5 is lower than that of the air 2 at the inlet of the distributor In both embodiments of the heat transfer system 17, 18, the high temperature heat transfer fluid passing through the upstream heat exchanger 5 is the engine coolant 3.  In both embodiments of the heat transfer system 17, 18, the high temperature heat transfer liquid and the low temperature heat transfer liquid do not mix when they are in circulation.  In these two embodiments, the heat transfer system 17, 18 comprises a high temperature circuit 19, that is to say the circuit of the engine coolant 3 (shown in solid lines) and a circuit Low temperature 20 (shown in dashes).  The high temperature circuit 19 comprises a main loop 21 whose input and output are connected to the motor 3.  This main loop 21 comprises a cooling branch 22, a branch branch 23 and a common branch 24.  The cooling branch 22 comprises, on the one hand, an upstream end connected to the motor 3 and forming an inlet of the main loop 21, and, on the other hand, a high temperature radiator 25 which is adapted to cool the coolant leaving the engine 3 by the outside air.  The branch branch 23 also comprises an upstream end connected to the engine 3 and forming an input of the main loop 21, and bypasses the high temperature radiator 23.  In order to distribute the high temperature heat transfer fluid between the cooling branch 22 and the bypass branch 23, the high temperature circuit 19 also comprises a bypass valve 26 which is controlled by a thermostat and which can take any position between a closed position in which all of the coolant is directed to the branch branch 23 (cf.  FIGS. 5 and 7) and an open position in which all the liquid is directed towards the cooling branch 22 (cf.  Figures 6 and 8).  The common branch 24 has the upstream end of the junction of the cooling branch 22 and the bypass branch 23, and its downstream end is the output of the main loop 21.  A pump 27 disposed in the common branch 24 makes it possible to circulate the high temperature heat transfer fluid in the high temperature circuit 19.  The high temperature circuit 19 also comprises a distributor loop 28 which comprises the upstream heat exchanger 5 of the air distributor 1.  In the present embodiments, the input and the output of the distributor loop 28 are arranged in the common branch 24, that is to say downstream of the junction of the cooling branch 22 and branch branch 23 (and here, upstream of the pump 27).  The fact that the input of the distributor loop 28 is disposed in the common branch 24 makes it possible to have a continuous flow and as independent as possible from the position of the bypass valve 26 and the operating conditions of the motor 3 and the motor vehicle.  Another advantage is the relatively low temperature of the high temperature heat transfer fluid at the inlet of the upstream heat exchanger 5.  Indeed, if the liquid comes only from the bypass branch 23, it leaves the engine 3 with a relatively low temperature but the flow of heat transfer liquid high temperature is reduced as the bypass valve 26 opens and vanishes when the bypass valve 26 is in full opening; if it comes solely from the cooling branch 22, it has been cooled by the high temperature radiator 25 but the high temperature heat transfer liquid flow rate in the upstream heat exchanger 5 is unavailable as long as the bypass valve 26 is closed and is then too dependent on the opening conditions of the bypass valve 26.  By arranging the input of the distribution loop 28 in the common branch 24, the high-temperature heat transfer liquid borrowing the input of the distribution loop 28 comes from the two branches 22, 23 and has a flow rate, for the same rotational speed of the pump 27, identical regardless of the position of the bypass valve 26, with a proportion from the cooling branch all the more important that the temperature of the liquid output of the engine 3 is high.  In the present embodiments, the high temperature circuit 19 also comprises a heater loop 29.  The heater loop 29 comprises, on the one hand, an upstream end connected to the motor 3 and forming a separate inlet of the inputs of the main loop 21, and, on the other hand, a heater 30 allowing the cooling liquid of the engine heats air to be sent into the passenger compartment.  The output of the heater loop 29 opens into the common branch 24 of the main loop 21, upstream of the pump 27.  [0086] Advantageously, the output of the heater loop 29 is downstream of the output of the splitter loop 28.  As a result, the heat transfers carried out at the level of the heater 30 do not disturb the high temperature heat transfer liquid circulating in the upstream heat exchanger 5, these heat transfers being dependent on numerous parameters: external temperature, temperature of the heat transfer liquid temperature at the output of the combustion engine 3, operation of the air-conditioning unit of the passenger compartment of the vehicle (depending on whether the distribution flaps are in position for recirculating the air in the passenger compartment or in the position for sucking in the air outside, according to the air flow through the heater 30, and the level of thermal comfort desired by the user in the cabin).  Moreover, because of the relative provisions of the output of the heater loop 29 and the input and output of the distributor loop 28, when the bypass valve 26 is open and allows the circulation of the high temperature heat transfer liquid in the radiator At a high temperature 25, the part of the high temperature heat transfer fluid which has passed through the heater 30 can not enter the upstream heat exchanger 5.  As a result, the cooling of the supercharged air by this exchanger 5 is more efficient since the temperature of the heat transfer liquid at the outlet of the heater 30 is greater than that at the outlet of the high temperature radiator 25 (ie the incoming air in the passenger compartment bypasses the heater 30 which is then the seat of any heat exchange, the air entering the passenger compartment passes through the heater 30 which is then the seat of a coolant coolant lower than the cooling taking place in the high temperature radiator since the heater 30 has intrinsic heat exchange performance lower than the radiator 25 and is irrigated by a lower fluid flow rate).  The low temperature circuit 20 comprises a main loop 31 in which the low temperature heat transfer fluid cyclically crosses the downstream heat exchanger 6 and a low temperature radiator 32 which allows the cooling of the low temperature coolant by air outside.  In the present embodiments, the main loop 31 of the low temperature circuit 20 also comprises a pump 33 which circulates the low temperature heat transfer liquid (and inject it into the downstream heat exchanger 6).  Typically, the pump 33 of the low temperature circuit 20 is an electric pump.  Finally, in both embodiments, the heat transfer system 17, 18 comprises a single degassing box 34 which pressurizes, degass and supply the high temperature circuit 19 and the low temperature circuit 20 with the same liquid (The supply is just upstream of the corresponding pump 27, 33).  The degassing box 34 is fed by the high temperature radiator 32 to which it is connected.  The degassing box 34 also ensures the thermal expansion of the high temperature heat transfer fluid in the high temperature circuit 19 and the low temperature heat transfer liquid in the low temperature circuit 20.  The fact of having only one degassing box makes it possible to fill the thermal transfer system with heat transfer liquid in one step.  In the first embodiment illustrated in Figures 5 and 6, the two high and low temperature circuits 19, 20 are hydraulically independent (except for their connection with the degassing box 34).  In Figure 5, the bypass valve 26 is in a position in which the cooling branch 22 is closed.  In such a configuration, the high temperature heat transfer liquid circulates in the branch branch 23, the common branch 24, the distributor loop 28 and the heater loop 29.  In Figure 6, the bypass valve 26 is in a position in which the branch branch 23 is closed.  In such a configuration, the coolant circulates in the cooling branch 22, the common branch 24, the distributor loop 28 and the heater loop 29.  In the second embodiment, the heat transfer system comprises a coupling valve 35 adapted, in the open position, to allow the circulation of the low temperature heat transfer liquid through the high temperature radiator 25.  The coupling valve 35 allows, in the open position, to put the high temperature radiator 25 and the low temperature radiator 32 in parallel.  This second embodiment makes it possible to increase the cooling potential of the low-temperature heat-transfer liquid before it enters the downstream heat exchanger 6 of the air distributor 1, by associating, with the low-temperature radiator 32, the high-temperature radiator 25 which is normally intended to cool the engine 3 (and in some cases the gearbox, especially if it is an automatic gearbox) and therefore has large dimensions, and which is not used so much that the bypass valve 26 is closed.  Thus, the heat exchange surface with the outside air offered to the low temperature heat transfer liquid is increased by limiting the costs and the size associated with this increase in heat exchange area.  More specifically, the coupling valve 35 is a four-way valve, two of which are connected to the high temperature cooling circuit 19 and two to the low temperature cooling circuit 20.  In the closed position, no channel of one of the two high and low temperature cooling circuits 19, 20 communicates with one channel of the other of these circuits.  In the open position, each channel of one of these two circuits communicates with one channel of the other circuit.  FIG. 7 illustrates the thermal system 18 with the bypass valve 26 in the closed position and the coupling valve 35 in the open position, the channel communicating with the inlet of the low temperature radiator 32 being connected to the channel communicating with the the inlet of the high-temperature radiator 25, and the channel communicating with the outlet of the low-temperature radiator 32 being connected to the channel communicating with the outlet of the high-temperature radiator 25.  The pump 33 sucks, on the one hand, the low temperature heat transfer liquid at the outlet of the low temperature radiator 32, and, secondly, because of the open position of the coupling valve 35, the low temperature heat transfer liquid at the outlet of the high-temperature radiator 25, and propels all of this liquid inside the downstream heat exchanger 6 of the air distributor 1.  At the outlet of the downstream heat exchanger 6, a first portion of the low temperature heat transfer fluid is directed at the inlet of the low temperature radiator 32 and, because of the open position of the coupling valve 35, a second part of the same coolant is directed to the inlet of the high temperature radiator 25.  The bypass valve 26 being closed, the second part of the low temperature coolant directed, via the coupling valve 35, to the high temperature cooling circuit 19 is totally directed towards the high temperature radiator 25.  The major portion of this second portion of low temperature heat transfer liquid entering the high temperature radiator 25 passes through the beam where the heat exchange with the outside air takes place, spring of the high temperature radiator 25 and, being unable to be directed towards the combustion engine 3 due to the closed position of the bypass valve 26, is sucked through the coupling valve 35 by the pump 33, and joined, at the inlet of the latter, the first part of the coolant liquid low temperature which, for its part, has passed through the low temperature radiator 32.  A tiny portion of the second portion of low temperature heat transfer liquid entering the high temperature radiator 25 takes the path practiced on the water box of the high temperature radiator 25, without crossing the beam where the heat exchange with the air takes place outside, and is directed towards the degassing box 34 at the output of which this tiny portion is directed towards the pump 33, thus contributing to the pressurization of the low temperature cooling circuit 20 and the priming of the pump 33.  FIG. 8 represents the thermal system 18 in a state where the bypass valve 26 is in the open position and where the coupling valve 35, in the closed position, ensures the hydraulic independence of the two high and low temperature circuits 19, 20 (except for their connection with the degassing box 34).  The control system controls the coupling valve 35 so that it is in the open position if and only if the bypass valve 26 drives all of the high temperature heat transfer liquid in the bypass loop 23.  In FIG. 7, the bypass valve 26 is in a position in which the cooling branch 22 is closed and the coupling valve 35 is open.  In such a configuration, the high temperature coolant circulates in the branch branch 23, the common branch 24, the distributor loop 28 and the heater loop 29, and the low temperature heat transfer liquid circulates in the high and low radiators. temperature 25, 32.  In Figure 8, the bypass valve 26 is in a position such that the bypass branch 23 is closed and the coupling valve 35 is closed.  In such a configuration, the cooling liquid circulates in the cooling branch 22 (including in the high temperature radiator 25), the common branch 24, the distributor loop 28 and the heater loop 29, and the low heat transfer liquid temperature circulates in the low temperature radiator 32.  The coupling valve 35 may be solenoid type controlled by a solenoid, the butterfly type or the thermostatic type controlled by the temperature of the coolant 5 at the outlet of the engine 3.  Advantageously, the control system is arranged so that there is an offset between the closing of the coupling valve 35 and the partial opening of the cooling branch 22, the closing of the coupling valve 35 being carried out. first.  This offset may result, for example, by a triggering of the closing of the coupling valve 35 by the achievement, by the high temperature coolant of the engine 3, of a lower threshold temperature (for example, of about 5 ° C) at the temperature triggering the partial opening of the cooling branch 22 by the bypass valve 26.  The present invention is not limited to the embodiments presented above.  The non-preferred alternative according to which, either the input and the output of the splitter loop 28, or only the input (the output of the splitter loop 28 then being downstream), are arranged downstream. the output of the heater loop 29, is within the scope of the present invention.  Likewise for the non-preferential alternative according to which the inlet of the distributor loop 28 is disposed on the heater loop 29 upstream, in series or in parallel with the heater 30.  In addition, the main loop 31 of the low temperature circuit 20 could be a low temperature branch of the high temperature circuit 19.  In such a case, it is possible for the heat transfer system to comprise only one pump, advantageously the pump 27 of the high temperature circuit 19 which is driven by the motor 3.  [00102] In order to ensure the additional cooling of the low temperature heat transfer liquid, in the low temperature circuit 20, the low temperature radiator 32 is upstream of the downstream heat exchanger 6 of the air distributor 1.  [00103] More precisely, it would be possible for the low temperature branch of the high temperature circuit 19 to be formed by a bypass loop whose input is downstream of the high temperature radiator 25 and upstream of the common branch 24.  Therefore, physically, a single radiator can be used consisting of two heat exchange parts arranged in series in the direction of flow of the coolant.  This radiator comprises an input and two outputs, a first intermediate output connected to the high temperature circuit 19 and a second output disposed at the end of the single radiator and connected to the low temperature circuit 20.  It would also be possible for the low temperature branch of the high temperature circuit 19 to be formed by a bypass loop, the input of which is made in the heater loop 29, preferably downstream of the heater 30.  It would also be possible for each high and low temperature cooling circuit 19, 20 each to have a degassing box of its own.  In this case, it is necessary to provide, at a high point of the engine compartment of the vehicle, a free space in order to implant the second degassing box.  The heat transfer system then needs to be filled with heat transfer liquid in two steps.  It would finally be possible to have low temperature radiators 32 and high temperature 25 other than in series with respect to each other vis-à-vis the flow of air from outside and entering by the vehicle grille in the engine compartment (as illustrated in Figures 5 to 8), for example one side, above or below the other, in a position in which the low temperature radiator 32 does not occupy the entire available area in the front module for cooling.  In addition, the invention relates to a heat transfer system comprising a combustion engine, a compressor adapted to compress the intake air of the engine, a circuit of the engine coolant which comprises a cooling branch emerging from the engine. engine and comprising a radiator adapted to cool the coolant by air, a bypass branch emerging from the engine and bypassing the radiator, and a common branch downstream of the junction of the cooling branch and the branch bypass circuit, the coolant circuit comprising a charge air heat exchanger adapted to exchange heat with the charge air prior to introduction into the engine, characterized in that the coolant circuit comprises a loop comprising the charge air heat exchanger and whose inlet is disposed in the common branch.  This thermal system can be combined with any characteristic of the heat transfer systems set forth in the present description, the supercharging air heat exchanger 5 being able to be in the air distributor or not.  

Claims (11)

REVENDICATIONS1. Air distributor (1) for a combustion engine (3), characterized in that it comprises a device adapted to exchange heat with charge air (2) for the combustion engine (3), the device comprising two heat exchangers (5, 6) connected in series with respect to the charge air (2), each heat exchanger (5, 6) being traversed by a coolant which, at the inlet of this exchanger (5, 6) has a temperature of its own. 2. air distributor (1) according to claim 1, characterized in that it comprises delimiting walls (7) forming its external structure, and to which the heat exchangers (5, 6) are fixed in a sealed manner so to correctly guide the charge air (2). 3. Air distributor (1) according to one of claims 1 to 2, characterized in that at least one of the two heat exchangers (5, 6) is a U-shaped exchanger. 4. air distributor (1) according to one of claims 1 to 3, characterized in that it comprises a bypass line (9) arranged to be in parallel with a first heat exchanger and in series with a second exchanger. 5. air distributor (1) according to one of claims 1 to 4, characterized in that it comprises a short-circuit passage (11) arranged to allow the supercharging air (2) of short circuit the two heat exchangers (5, 6). A heat transfer system (17, 18) comprising a combustion engine (3), the heat transfer system (17, 18) being adapted to cool charge air prior to admission to the engine, characterized in that it comprises an air distributor (1) arranged at the inlet of the motor (3) and according to one of claims 1 to 5. 7. Thermal transfer system (17, 18) according to claim 6, characterized in that the distributor comprises at its air inlet, a distribution valve (12) at several positions adapted to impose the supercharging air ( 2) its circulation in the distributor (1), said heat transfer system further comprising a control system adapted to control the position of the distribution valve (12) as a function of the charge air temperature (2) and engine speed and load (3). 8. Heat transfer system (17, 18) according to claim 7, characterized in that it is associated with a high-pressure recirculation system of the combustion gases adapted to introduce the recirculation gas into the air distributor (1). ). Thermal transfer system (17, 18) according to one of claims 7 to 8, characterized in that the control system is arranged to control the position of the distribution valve (12) in the heat transfer position. and to block the circulation of the low temperature coolant in the downstream heat exchanger (6) when the engine (3) requires a supply of heated air. 10.Heat transfer system (17 18) according to one of claims 6 to 7, characterized in that the coolant passing through the upstream heat exchanger (5) is the engine coolant, and in that the circuit (19) of the engine coolant (3) comprises a distributor loop (28) which comprises the upstream heat exchanger (5) of the air distributor (1) and whose inlet is disposed downstream of the junction of a cooling branch (22) and a bypass branch (23), the cooling branch (22) comprising a high temperature radiator (25) adapted to cool the coolant leaving the engine (3) , and the bypass branch bypassing this radiator (25). 11.Heat transfer system (17, 18) according to one of claims 6 to 10, characterized in that it comprises a low temperature heat transfer liquid circuit (20) in which the low temperature heat transfer liquid cyclically crosses the heat exchanger downstream heat source (6) of the air distributor (1) and a low temperature radiator (32) for cooling it.