EP1966473B1 - Motor vehicle thermal management device - Google Patents

Abstract

The heat management system for a motor vehicle with a preferably supercharged internal combustion engine with main and secondary cooling circuits and interconnection differs by having the first and second inlets (21a, 21b) of the main radiator (2) first section (21) connected respectively to first and second pipes (112, 113) of the high-temperature loop (11), and the first inlet (22a) of the second section (22) connected to the low-temperature loop (31) and to the first section's first inlet via the fluid communication system (27). The interconnection system comprises a series of four-way valves (4) connected to the radiator inlets and the low-temperature loop.

Description

The present invention relates to a thermal management device for a motor vehicle equipped with a heat engine, in particular a supercharged internal combustion engine.

To reduce the consumption and polluting emissions of motor vehicles, various technological developments have been proposed by manufacturers in the field of combustion, supercharging, and exhaust gas treatments. These developments require the search for new thermal management devices to evacuate an increasing amount of heat from the engine, especially at high speed and high load, and to cool the engine air supercharging, some of the gases of the engine. exhaust systems before their reintroduction into the combustion chamber, referred to as recirculated exhaust gas or EGR (Exhaust Gas Recirculation) gas, and, if applicable, the air-conditioning air conditioning condenser of the passenger compartment and the electrotechnical components for hybrid vehicles.

The thermal management devices conventionally comprise a conventional cooling main circuit of the heat engine, equipped with a main pump and a high temperature main radiator, and a secondary low temperature cooling circuit, equipped with a secondary pump and a secondary radiator operating at low temperatures to evacuate all the calories from the charge air and the EGR gases.

For charge air, especially in the case of double turbocharging turbochargers or turbochargers and mechanical compressors, the temperature of the coolant must be weaker and weaker to meet ever more stringent pollutant emission standards. Furthermore, there is an increase in the EGR gas rate, it can remain high even for high speeds and loads of the engine, which increases the amount of heat to be removed by the secondary circuit. The secondary radiator can not evacuate a large amount of heat given the small temperature difference between the coolant and the ambient air, it is very difficult to keep the coolant at low temperature in the secondary circuit. Increasing the size of the secondary radiator would have a negative impact on the high temperature radiator since it would decrease the overall air velocity on the cooling case and increase the air temperature upstream of the high temperature radiator. To be able to evacuate the calories of the main circuit, it would then be necessary to increase also the size of the main radiator which already has a very large frontal area.

For the cooling of the secondary circuit, it has been proposed in the patent document FR 2,832,187 to use the main radiator. This patent document notably describes interconnection means between the main circuit and the secondary circuit, formed by two 3-way valves and a 4-way valve, which make it possible to integrate the main radiator in the low temperature loop. In another embodiment, this patent document proposes to cut the main radiator into two sections. One of the two sections may be used to assist the coolant cooling of the low-power secondary circuit of the engine, and this radiator section will be returned to the high-power main circuit of the engine. The switchover of this section of a cooling loop to the other loop is done through interconnection means formed either of two 4-way valves located on each side of the main radiator, or a single 6-way valve.

This device is satisfactory when the power transferred in the secondary circuit is relatively low, but requires either several valves or a single 6-way valve with a large number of pipes that makes the circuits complex and expensive, and creates additional pressure drops involving an increase in the power and cost of circulation pumps. Furthermore, the cooling of the secondary circuit may be insufficient when the EGR gas rate increases.

The object of the present invention is to provide a thermal management device overcoming the aforementioned drawbacks, which allow efficient cooling of the secondary circuit at low temperature, while remaining simple design.

• un circuit principal de refroidissement à haute température, comprenant une boucle haute température équipée d'un radiateur principal à haute température et de moyens de circulation d'un liquide de refroidissement entre ledit radiateur principal et le moteur, la surface d'échange du radiateur principal étant scindée en au moins une première section, avec une première et une deuxième entrée pour la circulation de fluide, et une seconde section avec une première entrée et une deuxième entrée pour la circulation de fluide,
• un circuit secondaire de refroidissement à basse température, comprenant une boucle basse température équipée d'un radiateur secondaire à basse température et de moyens de circulation d'un liquide de refroidissement à basse température, et
• des moyens d'interconnexion reliant le circuit principal et le circuit secondaire, lesdits moyens d'interconnexion permettant d'intégrer les deux sections du radiateur principal au circuit principal ou d'intégrer la première section au circuit principal et la deuxième section au circuit secondaire,

caractérisé en ce que

• la première entrée et la deuxième entrée de la première section du radiateur principal sont connectées respectivement à une première conduite de radiateur principal et une deuxième conduite de radiateur principal de la boucle haute température, la première entrée de la deuxième section étant connectée à la boucle basse température, en amont du radiateur secondaire, et reliée à la première entrée de la première section par des moyens de communication fluidique,
• lesdits moyens d'interconnexion comprenant un système de vannes à quatre voies connecté par une première voie à la deuxième conduite de radiateur principal, par une deuxième voie à la deuxième entrée de la deuxième section du radiateur principal, et intercalé sur la boucle basse température, en aval du radiateur secondaire par une troisième voie, et en amont du radiateur secondaire par une quatrième voie, la première entrée de la deuxième section étant reliée à la boucle basse température entre le radiateur secondaire et la quatrième voie du système de vannes,
• ledit système de vanne étant apte
  • à mettre en communication d'une part la première voie et la deuxième voie et d'autre part la troisième voie et la quatrième voie pour séparer le circuit principal et le circuit secondaire, en intégrant la première et la deuxième section du radiateur principal dans la boucle haute température, dans un fonctionnement en mode normal à régime et charge élevés,
  • à mettre en communication la troisième voie et la deuxième voie pour intégrer la deuxième section du radiateur principal dans la boucle basse température, dans un fonctionnement en mode normal à régime et charge modérés, avec refroidissement renforcé du circuit secondaire, et
  • à mettre en communication la troisième voie avec la première voie et la deuxième voie pour intégrer la deuxième section et au moins en partie la première section du radiateur principal dans la boucle basse température, dans un fonctionnement en mode normal à régime et charte modérés, avec refroidissement très renforcé du circuit secondaire.

For this purpose, the subject of the present invention is a thermal management device for a motor vehicle equipped with a heat engine, in particular a supercharged internal combustion engine, comprising:

• a high temperature cooling main circuit, comprising a high temperature loop equipped with a high temperature main radiator and means for circulating a cooling liquid between said main radiator and the engine, the exchange surface of the main radiator being split into at least a first section, with a first and a second inlet for fluid circulation, and a second section with a first inlet and a second inlet for fluid circulation,
• a secondary low temperature cooling circuit, comprising a low temperature loop equipped with a secondary radiator at low temperature and means for circulating a coolant at low temperature, and
• interconnection means connecting the main circuit and the secondary circuit, said interconnection means making it possible to integrate the two sections of the main radiator with the main circuit or to integrate the first section with the main circuit and the second section with the secondary circuit,

characterized in that

• the first inlet and the second inlet of the first section of the main radiator are respectively connected to a first main radiator pipe and a second main radiator pipe of the high temperature loop, the first inlet of the second section being connected to the bottom loop. temperature, upstream of the secondary radiator, and connected to the first inlet of the first section by means of fluid communication,
• said interconnection means comprising a four-way valve system connected by a first path to the second main radiator pipe, by a second path to the second inlet of the second section of the main radiator, and interposed on the low temperature loop, downstream of the secondary radiator by a third channel, and upstream of the secondary radiator by a fourth channel, the first inlet of the second section being connected to the low temperature loop between the secondary radiator and the fourth channel of the valve system,
• said valve system being suitable
  • communicating on the one hand the first lane and the second lane and on the other hand the third lane and the fourth lane to separate the main circuit and the secondary circuit, by integrating the first and the second section of the main radiator in the high temperature loop, in normal mode operation at high speed and load,
  • communicating the third channel and the second channel to integrate the second section of the main radiator into the low temperature loop, in normal mode operation at moderate speed and load, with enhanced cooling of the secondary circuit, and
  • to port the third channel with the first channel and the second channel to integrate the second section and at least partly the first section of the main radiator into the low temperature loop, in a normal mode operation with moderate speed and chart, with very reinforced cooling of the secondary circuit.

The present invention provides a simple and compact thermal management device with a single four-way valve system, in particular to use part or all of the main radiator for cooling the liquid of the secondary loop at moderate speed and load. of the engine. The device according to the invention has a high caloric evacuation capacity of the integrated components on the secondary circuit for cooling at low temperature, in particular the EGR / liquid gas radiator, the charge air / liquid radiator, the air conditioning condenser, and / or electrotechnical components in the case of a hybrid vehicle. The thermal management device according to the invention makes it possible to meet the cooling needs of the EGR gases, in particular for high EGR gas rates, and the cooling requirements of the supercharged air for a high thermal power, as in the case of a double supercharging.

According to a particularity, the valve system is able to put the first channel in communication with the second and third ways for cooling the heat engine using the secondary radiator, in a mode of operation in degraded mode. The device according to the invention thus makes it possible to meet the cooling needs of the high-power engine, with maximum cooling of the heat engine.

According to another particularity, the valve system is able to put in communication the first channel and the third channel for cooling the heat engine and any members mounted on the high temperature loop, such as the turbocharger bearing, during the hot shutdown of the engine, in a cooling mode operation of the engine.

According to one embodiment, the main circuit comprises a main thermostat on the first main radiator pipe to cut, in a closed position, and allow, in an open position, the flow of fluid towards the main radiator. The cooling device advantageously comprises a bypass line connecting the first main radiator pipe, upstream of the main thermostat, to a heat recovery thermostat, mounted on the connecting pipe from the first inlet of the second section to the low loop. temperature, said thermostat placing in communication the second section with the low temperature loop in an open position, for said operation in degraded mode and in normal mode with reinforced and very reinforced cooling, or the bypass line with the low temperature loop in a closed position, for the recovery of calories in a cold start mode operation and / or in heating mode of the passenger compartment when the engine stops, operation in which the valve system communicates the first channel and the third channel . The device according to the invention thus enables the recovery of calories from the secondary circuit, including radiators RAS and EGR to accelerate the temperature rise of the engine during the cold start of the engine, and the recovery of calories stored in the engine and the coolant for maintaining the heating of the engine cockpit when stopping the engine, as for example, on hybrid vehicles incorporating the Stop and Start function (stopping the engine during a prolonged stop in traffic jam or during a long stop where the driver would remain in the vehicle and would require heating).

Advantageously, the low temperature loop comprises a bypass line of the low temperature radiator connected upstream of the secondary radiator to a heat recovery thermostat.

According to one embodiment, said valve system comprises four controlled two-way valves: a first valve connecting the first and third channels, a second valve connecting the second and third channels, a third valve connecting the first and second channels and a fourth valve; valve connecting the third and fourth lanes.

According to one embodiment, the main radiator is formed of a single exchanger with a first and a second header, the first and second sections being defined by a bulkhead and a honeycomb partition respectively positioned in the first and the second manifold, said honeycomb partition constituting said fluid communication means. The lower portions of the first and second manifolds respectively comprise the second and first entrances of the second section. The upper portions of the first and second manifolds respectively comprise the second and the first inlet of the first section, or the first box comprises a second bulkhead defining an upper portion and an intermediate portion respectively provided with the first and second inlet of the first section, to form a first section with two passes.

Alternatively, the main radiator is formed of two separate exchangers each forming a section of the main radiator, each exchanger having two manifolds, each manifold comprises a section inlet, the manifolds provided with the first inputs are for example connected by a tube forming the fluidic communication means.

The low temperature loop advantageously incorporates a charge / liquid air radiator, called RAS radiator, and a recirculated / liquid exhaust gas radiator, called EGR radiator. According to one embodiment, the EGR radiator and / or the radiator RAS comprise upstream downstream with respect to the gaseous flows passing through them, at least one high temperature part, connected to the main circuit, and a low temperature part connected to the secondary circuit. for cooling at two temperature levels of said gas flows. The use of such radiators at two temperature levels allows efficient cooling of the charge air and / or EGR gas, especially in case of high EGR gas recirculation rate, and / or in case of extension of the zone (engine torque regime) for recirculating gases at high speeds and heavy loads. They also allow operation in cold start mode in the absence of bypass line associated with a heat recovery thermostat.

• la figure 1 représente une vue schématique d'un dispositif de gestion thermique pour un véhicule automobile équipé d'un moteur à combustion interne suralimenté selon un premier mode de réalisation de l'invention ;
• la figure 2 représente un exemple de réalisation du système de vanne à quatre voies ;
• les figures 3A et 3B illustrent deux variantes de réalisation de l'insertion de la cloison du nid d'abeille dans le radiateur principal ;
• les figures 4A et 4B représentent deux vues schématiques d'un radiateur principale pour le dispositif de la figure 1 selon deux variantes de réalisation ;
• les figures 5 à 12 représentent des vues schématiques du dispositif de gestion thermique de la figure 1 illustrant différents modes de fonctionnement ;
• la figure 13 représente une vue schématique d'un dispositif de gestion thermique selon un deuxième mode de réalisation ; et,
• la figure 14 représente une vue schématique d'un dispositif de gestion thermique selon une variante du deuxième mode de réalisation de la figure 13.

The invention will be better understood, and other objects, details, features, and advantages will become more clearly apparent from the following detailed explanatory description of embodiments. presently preferred embodiments of the invention, with reference to the appended schematic drawing, in which:

• the figure 1 is a schematic view of a thermal management device for a motor vehicle equipped with a supercharged internal combustion engine according to a first embodiment of the invention;
• the figure 2 represents an embodiment of the four-way valve system;
• the Figures 3A and 3B illustrate two alternative embodiments of the insertion of the honeycomb partition into the main radiator;
• the Figures 4A and 4B represent two schematic views of a main radiator for the device of the figure 1 according to two variants;
• the Figures 5 to 12 represent schematic views of the thermal management device of the figure 1 illustrating different modes of operation;
• the figure 13 is a schematic view of a thermal management device according to a second embodiment; and,
• the figure 14 represents a schematic view of a thermal management device according to a variant of the second embodiment of the figure 13 .

With reference to the figure 1 , the thermal management device according to the invention comprises two cooling circuits, a first high-temperature cooling circuit, called primary or high temperature 1, at a conventional temperature level of the order of 90 to 100 ° C, a second low temperature cooling circuit, said secondary or low temperature 3, at a relatively low temperature level, of the order of 50 to 60 ° C, and a 4-way valve system, designated by the reference 4, allowing to make communications between the main circuit and the secondary circuit.

The main circuit conventionally comprises, in series on a secondary or high temperature loop 11, the combustion internal combustion engine 9, a main radiator or high temperature radiator 2, and a main pump 13, for example a mechanical pump driven by the engine, for the circulation in the circuit of a high temperature coolant, said liquid HT. The high temperature loop comprises a motor duct 111 on which is mounted the motor 9 and the main pump 13, a first main radiator duct 112 and a second main radiator duct 113 connecting the main radiator to the motor duct 111, respectively downstream and upstream of the engine with respect to the direction of circulation of the HT liquid at the engine.

The main circuit comprises an expansion tank 14 for filling and pressure regulation of the circuit, a heating radiator of the passenger compartment or heater 15, and a turbocharger bearing 16, each of them being mounted in a bridge between the first and the second main radiator pipe. This main circuit can integrate other members of the propulsion engine group to cool conventionally at high temperature, including water / oil lubrication of the engine and automatic gearbox.

A main thermostat 17, for example of single-acting wax type or pilot-type, or a main thermostatic valve ground two-way, is interposed on the first radiator pipe 111, to cut in a closed position or allow in a position open the circulation of fluid in the first radiator pipe towards the main radiator, in order to regulate the temperature of the liquid HT.

The secondary circuit 3 comprises a secondary low temperature loop 31 which comprises a pipe secondary radiator 311 on which are mounted a secondary radiator or low-temperature radiator 32, and a secondary pump 33, for example electric, for the circulation of the coolant coolant low temperature, said liquid BT. The secondary loop includes a charge air / liquid cooler 34, said RAS exchanger, and an EGR / liquid gas cooler 35, said EGR exchanger, these two exchangers being for example connected in parallel to the low temperature loop downstream of the secondary radiator, as illustrated on the figure 1 . A first three-way heat recovery thermostat 36, for example of double-acting wax type, is interposed on the secondary radiator pipe by two of its channels, upstream of the secondary radiator, a bypass line 37 connecting the third This heat recovery thermostat is routed to the secondary radiator duct downstream of the secondary radiator. Below a BT fluid set point temperature, the heat recovery thermostat is in a closed position in which the BT fluid bypasses the low temperature radiator through the bypass line. Above this set temperature, the heat recovery thermostat is in an open position in which the fluid BT passes through the low temperature radiator.

The main radiator 2 consists of a single exchanger cut into a first heat exchange section 21 and a second heat exchange section 22. The first section comprises a first inlet 21a for its connection to the first radiator pipe main 112 and a second input 21b for its connection to the second main radiator pipe. The second section includes a first input 22a for its connection to the low temperature loop and a second input 22b for its connection to one of the channels of the valve system, as described below.

In the embodiment illustrated in figure 1 , the main radiator comprises tubes equipped with cooling fins, a first manifold 23 and a second manifold 24 located at the ends of the tubes. The first manifold is separated into an upper portion 23a, an intermediate portion 23b and a lower portion 23c, by a first and. a second separating bulkhead, respectively 25 and 26. The second box is separated into an upper portion 24a and a lower portion 24b, by a honeycomb partition 27 disposed at the same level as the second partition 26. The first and second sections are thus delimited by the second partition 26 and the honeycomb partition 27, the upper part 23a and the intermediate part 23b of the first box respectively comprising the first inlet 21a and the second inlet 21b of the first section to form a first two-pass section, the lower portion 23c of the first header and the lower portion 24b of the second manifold respectively comprising the second inlet 22b and the first inlet 22a of the second section.

The 4-way valve system comprises a first channel 41 connected by a connecting pipe 114 to the second main radiator pipe 113, a second channel 42 connected by a pipe 115 connecting to the second inlet 22b of the second radiator section main, a third channel 43 connected to the secondary radiator duct 311 downstream of the secondary pump and the RAS and EGR exchangers, and a fourth channel connected to the low temperature radiator pipe upstream of the secondary pump, the valve system so being interspersed on the low temperature loop through its third and fourth lanes.

The first inlet 22a is connected by a connecting pipe 38 to the low temperature loop, upstream of the secondary pump with respect to the direction of fluid flow, between the secondary pump and the valve system.

The main circuit further comprises a bypass line 18 connecting the first main radiator pipe, upstream of the main thermostat 17, to the low temperature loop via a second three-way heat recovery thermostat 5. This second thermostat is mounted in series by two of its channels on the connecting pipe 38, the bypass line being connected to its third channel. Below a set temperature, this heat recovery thermostat is in a so-called closed position in which the bypass line is in communication with the low temperature loop. Above this setpoint temperature, this thermostat is in an open position in which the second section is in communication with the low temperature loop.

• communication entre les voies 41. et 43, pour coupler le circuit principal et le circuit secondaire, avec le thermostat principal 17 et le deuxième thermostat de récupération de chaleur 5 en position fermée, le premier thermostat de récupération de chaleur 36 étant en position ouverte ou fermée ;
• communication entre les voies 42 et 43, pour intégrer la deuxième section du radiateur principal au circuit secondaire, avec le thermostat principal et le deuxième thermostat de récupération de chaleur en position ouverte ;
• communication entre les voies 43 et 41 et entre les voies 43 et 42, pour intégrer la deuxième section et la majorité de la première section au circuit secondaire, avec le thermostat principal en position fermée, et le deuxième thermostat de récupération en position ouverte ;
• communication entre les voies 41 et 42 et entre les voies 43 et 44, pour séparer les deux circuits, avec le thermostat principal en position ouverte, et le deuxième thermostat de récupération en position ouverte ou fermée ; et
• communication entre les voies 41 et 42 et les voies 41 et 43, pour coupler les deux circuits, avec le thermostat principal et le deuxième thermostat de récupération en position ouverte.

The valve system allows the following five communication modes to be established between the 4 channels:

• communication between the channels 41 and 43, for coupling the main circuit and the secondary circuit, with the main thermostat 17 and the second heat recovery thermostat 5 in the closed position, the first heat recovery thermostat 36 being in the open position or closed;
• communicating between the channels 42 and 43, to integrate the second section of the main radiator with the secondary circuit, with the main thermostat and the second heat recovery thermostat in the open position;
• communicating between the channels 43 and 41 and between the channels 43 and 42, to integrate the second section and the majority of the first section to the secondary circuit, with the main thermostat in the closed position, and the second recovery thermostat in the open position;
• communication between the channels 41 and 42 and between the channels 43 and 44, to separate the two circuits, with the main thermostat in the open position, and the second recovery thermostat in the open or closed position; and
• communication between the channels 41 and 42 and the channels 41 and 43, for coupling the two circuits, with the main thermostat and the second recovery thermostat in the open position.

With reference to the figure 2 this valve system consists for example of four 2-way valves: a first valve 45 connecting the channels 41 and 43, a second valve 46 connecting the channels 42 and 43, a third valve 47 connecting the channels 41 and 42, and a fourth valve 48 connecting the channels 43 and 44.

The honeycomb partition 27 may consist of a perforated body of vertical holes through, or an assembly of small cross plates. With reference to the figure 3A , the honeycomb partition 27 is interposed between the ends of two consecutive tubes 28a, 28b of the main radiator, its thickness e being less than or equal to the spacing between the two consecutive tubes. The honeycomb partition ensures a fluid connection between the two sections of the main radiator, at the level of the second header, while avoiding or limiting the mixing between the fluid HT of the first section and the fluid BT of the second section when the latter are dedicated respectively to the main circuit and the secondary circuit. In the latter case, the honeycomb partition allows a small flow of fluid from the circuit secondary to the main circuit due to the expansion of the fluid during the temperature rise phase of the secondary circuit, the flow rate of fluid passing through the honeycomb becoming zero thereafter by the conservation of the mass of fluid contained in the two circuits. This honeycomb partition saves an expansion tank in the low temperature loop, allowing the evacuation of the expanded water volume to the first section of the main radiator which is in communication with the expansion tank 14 of the main circuit. The honeycomb partition therefore plays the role of an expansion vessel. When the first and second sections of the main radiator have to be connected to the main circuit by the action of the valve system 4, the honeycomb partition makes it possible to pass the fluid from the upper part to the lower part of the second. box to feed the second part of the radiator. When the two sections are to be connected to the secondary circuit, the honeycomb partition makes it possible to pass the fluid from the upper part to the lower part of the second box to allow the fluid to pass into the first section.

In an embodiment variant illustrated in figure 3B , the honeycomb partition 270 is advantageously inserted into the second box so as to plug an intermediate tube 28c, and thus separate the two adjacent tubes 28a and 28b 'respectively belonging to the first section and the second section, so to limit thermal exchanges between them. The thickness e of the honeycomb partition can then be increased for a better reduction of turbulence when the sections are dedicated to different circuits.

In an alternative embodiment, the main radiator comprises a first section with a single pass ( Figure 4A ), its first input being moved to the second manifold, and the first partition 25 above is removed. With reference to the Figure 4A the radiator 102 with two sections 121 and 122 then comprises a first box 123 separated in two by a bulkhead 126, and a second box 124 separated as previously in two by a honeycomb partition 127, the upper parts 124a and 123b of the second box and the first box, respectively, respectively comprise the first input 121a and the second input 121b of the first section, the lower portions 123c and 124b of the first box and the second box respectively comprise the second input 122b and the first input 122a of the second section.

For reasons of architecture and / or power to be evacuated by the device, it can be provided a main radiator consisting of two separate exchangers. With reference to the Figure 4B , the main radiator 202 then comprises a first exchanger forming the first section 221, which comprises a first box 223b provided with the second input 221b and a second box 224a provided with the first input 221a, and a second exchanger forming the second section 222 which comprises a first box 223c provided with the second input 222b and a second box 224b provided with the first input 222a, the second boxes 224a and 224b of the two exchangers being in fluid communication via a connecting pipe 227.

In alternative embodiments, the secondary loop integrates the condenser of an air conditioning circuit and / or one or more other exchangers for the low temperature cooling of other components, in particular for the cooling of the charge air for the engines. double turbocharging, and for cooling the machine electrical and power electronics on a hybrid vehicle, these exchangers being for example disposed between the channel 43 of the valve system and the RAS exchangers and EGR connected in parallel.

According to another variant, the two heat exchangers RAS and EGR are arranged in series on the low temperature loop, the RAS exchanger being disposed upstream of the EGR exchanger relative to the direction of circulation of low temperature fluid leaving the secondary radiator. The two exchangers are for example arranged between the secondary radiator and the channel 43 of the valve system. According to another configuration, the heat exchanger RAS is disposed between the secondary radiator and the channel 43, and the EGR exchanger is disposed between the channel 44 and the secondary radiator, for example between the connection point of the connecting pipe 38 on the secondary radiator. the secondary loop and the secondary pump.

A description of the different types of operation of the thermal management device of the figure 1 will now be done with reference to Figures 5 to 14 .

The figure 5 illustrates operation in cold start mode, with heat recovery from the RAS and EGR exchangers. During a cold start, it is interesting to accelerate the rise in temperature of the high temperature loop of the engine to reduce overconsumption and pollutant emissions related to the low temperature of the engine, and to improve the heating of the engine. in this mode, the main thermostat 17, and the heat recovery thermostats 36 and 5 are in the closed position to cut the fluid passage in the first section and the second section of the main radiator and in the secondary radiator, so that the fluid is not cooled by the ambient air, and the valve system communicates the track 41 and the track 42 to connect the secondary radiator pipe downstream of the EGR and RAS exchangers to the second radiator pipe 114 and thus put in communication the two loops.

The fluid heated by the RAS and EGR exchangers, and any other components mounted on the low temperature loop, enters the main circuit via the valve system to heat the engine and the passenger compartment, and returns to the low temperature loop via the bypass line 18. The circulation of fluid in the two loops is ensured by the main pump, the electric secondary pump possibly being able to be turned on.

The figure 6 illustrates a cold start mode operation similar to the previous one, with in addition a cooling by the low temperature radiator. After the start-up described above, the fluid of the low temperature loop can reach a temperature level which exceeds the maximum set temperature for the cooling of the heat exchangers RAS and EGR, the first heat recovery thermostat 36 goes into the open position for that the fluid is cooled in the low temperature radiator before entering the RAS and EGR exchangers.

The figure 7 illustrates operation in normal mode at moderate speed and load, with enhanced cooling of the secondary circuit. When the engine is running at moderate speed and load, it can be cooled by the first section of the main radiator. The second section of this radiator is used to reinforce the cooling of the BT fluid of the low temperature loop. The valve system 4 communicates the channels 43 and 42 to integrate the second section of the main radiator with the low temperature loop. The BT fluid first passes through the second section of the main radiator via the connecting line 115, through the secondary pump via the connecting pipe 31 with the thermostat 5 in the open position, then by the low temperature radiator before passing through the RAS exchanger and the EGR exchanger. In this mode, the two loops are independent, the main thermostat 17 can be opened or closed to allow the passage or not HT fluid in two passes in the first section of the main radiator.

The figure 8 illustrates a normal mode operation at moderate speed and load with a very strong cooling of the secondary circuit, the main thermostat in the closed position. To obtain a low temperature liquid very close to the ambient temperature and in particular to cool the RAS and / or EGR exchangers before the opening of the main thermostat, the valve system is controlled to establish the communication between the channels 41 and 43 and between the channels. 43 and 42 and thus pass the liquid BT low temperature loop both in the second section and in the second pass of the first section defined at the intermediate portion 23b of the first manifold. The fluid BT passes through the second section of the main radiator via the connecting pipe 115, and the first section via the connecting pipe 114 and the second radiator pipe 113 connected to the second inlet 21b. The fluid exits this first section via the honeycomb partition and then leaves the main radiator with the fluid of the second section through the first inlet 22a. The fluid then passes through the secondary pump via the connecting pipe with the thermostat 5 in the open position, and the low temperature radiator before passing through the RAS and EGR exchangers.

In the variant using the radiators 102 and 202 of the Figures 4A and 4B , the whole of the exchange surface of the first section of the radiators is used for the low temperature loop.

The figure 9 illustrates normal mode operation at high speed and load. When the engine develops a lot of power, the calories to be evacuated by the main circuit are important. The entire main radiator should be used for cooling. The valve system 4 communicates between the channels 41 and 42, and between the channels 43 and 44, the two circuits are independent. With the main thermostat in the open position, the fluid HT enters the first section of the main radiator through the first inlet 21a. Part of the fluid arriving in the second box spring from the first section through its second inlet 21b, the other part passes through the second section via the honeycomb partition to emerge through the second inlet 22b. The cooled fluid exiting the first section through the second radiator pipe 113 and exiting the second section through the connecting pipe 115 and the connecting pipe 114 then passes into the engine. The flow of fluid in the low temperature loop, with or without passage in the low temperature radiator is provided by the secondary pump. In this mode, the position of the thermostat 5 does not affect the independence of the two loops.

The figure 10 illustrates a degraded mode operation for the RAS and EGR exchangers, with maximum cooling of the heat engine assisted by the low temperature radiator. In the case of a use of the vehicle outside the specifications for which it has been dimensioned, or a malfunction, including a main non-operating thermostat, for example in blocked mode, or clogged main radiator tubes or when the vehicle is operating under very severe climatic and / or driving conditions, for example at an ambient temperature of 45 ° C, on a climb with a caravan, or on highway at maximum speed, the engine cooling can be very critical on some vehicles of strong motorization. So that the vehicle is always available and rolling, the device allows to use the low temperature radiator for the cooling of the engine. This corresponds to a degraded mode for the RAS exchanger and the EGR, their cooling is no longer ensured in order to protect the operation of the engine. The valve system 4 communicates between the channels 41 and 42, and between the channels 43 and 41, the thermostats 17, 5 and 36 are all in the open position. The fluid leaving the engine passes through the two sections of the main radiator as before, and a portion of the fluid arriving in the lower part of the second box passes through the connecting pipe 38 connected to the first inlet, to pass into the low temperature loop, where it is cooled by the low temperature radiator before joining at the connecting pipe 114 the fluid leaving the second section. In this mode, the secondary pump can be activated to promote fluid circulation in the low temperature loop by drawing fluid through the second inlet of the second section.

The figure 11 illustrates operation in cooling mode of the engine and the turbocharger bearing after hot shutdown of the engine, by the secondary pump 36. After the heat cut of the engine, the combustion gases can locally overheat the engine and / or the metal masses very hot around the turbocharger bearing may overheat the bearing lubricating oil. To protect the engine and the turbocharger, particularly its bearing, against overheating when the engine is stopped, and to avoid accelerated aging of the lubricating oil, the electric secondary pump is started just after the engine stop, and the valve system 4 communicates the channels 41 and 42 to circulate the liquid in the engine and the turbocharger. After stopping the engine, and thus stopping the main pump, the liquid arriving in the upper part of the second header, after having crossed the first exchange section, enters the lower part of the second box via the honeycomb partition, passes through the connecting pipe 38, with its heat recovery thermostat in the open position, then goes into the loop 'low temperature, where it is cooled by the secondary radiator before joining the pipe of radiator 113 via the connecting line 114 for cooling the engine and the turbocharger bearing. The secondary pump can also be used after the engine is shut down to circulate the liquid in the air heater to ensure the thermal comfort of the passenger compartment.

The figure 12 illustrates operation in maintaining mode of the passenger compartment heater. The valve system 4 communicates the channels 41 and 42, as in the previous mode, with this time the thermostats 5, 36 and 17 in the closed position to use the calories stored in the fluid and in the engine for heating cockpit after stopping the engine. This mode of operation proves very interesting for a hybrid vehicle with the "Stop and Start" function (shutdown of the engine during a prolonged stop)

The figure 13 represents a simplified embodiment of the device of the figure 1 , in which the bypass line 18 and the thermostat 5 are removed, the second inlet of the second section being simply connected to the low temperature loop by the connecting pipe 38. This device is more economical and simpler, has the same functionalities that the device of the figure 1 , except for maintaining cabin heating mode ( figure 12 ) and two cold start modes ( Figures 5 and 6 ) above.

The figure 14 represents an alternative embodiment of the second embodiment in which the EGR and / or RAS exchangers are first cooled with the HT liquid of the high temperature loop, then with the BT liquid of the low temperature loop. The exchangers RAS 134 and EGR 135 are each separated into two parts for cooling its gas flow at two temperature levels. Each exchanger comprises a low temperature portion connected to the secondary circuit via an inlet 134a, 135a and an output 134b, 135b, and a high temperature portion connected to the main circuit via an input 134c, 135c and an output 134d, 135d. The RAS exchanger comprises an upstream inlet and a downstream outlet for its series connection to the intake air circuit of the engine, so that the charge air passes into the exchanger by passing through the high temperature part and then the low temperature part. The EGR exchanger comprises an upstream inlet and a downstream outlet for the series connection of the RAS exchanger on the engine's EGR gas circuit, so that the EGR gases pass through the high temperature part and then the low temperature part.

As shown in figure 14 , the low temperature parts are connected in parallel on the low temperature loop by their input and output. The high temperature parts are connected in series on the main circuit, between the first and the second main radiator duct 112 and 113, so that the HT fluid leaving the engine passes into the high temperature part of the RAS exchanger and then into the of the EGR exchanger. The inlet 134c of the high temperature portion of the RAS exchanger is connected via a pipe 116 to the first radiator pipe main 112, and its output 134d is connected by a pipe 117 to the inlet 135c of the high temperature part of the EGR heat exchanger, the outlet 135d of the latter being connected to the second main radiator pipe 113 by a pipe 118.

This variant allows operation in cold start mode illustrated on the figure 14 , in which none of the channels of the valve system communicate to recover the heat of these two exchangers and thus accelerate the temperature rise of the engine.

Claims (10)

1. Thermal management device for a motor vehicle equipped with a heat engine, in particular with a supercharged internal combustion engine, comprising

   - a main high-temperature cooling circuit comprising a high-temperature loop equipped with a main high-temperature radiator and with means for circulating a cooling liquid between the said main radiator and the engine, the heat-exchange area of the main radiator being divided into at least a first section, with a first and a second inlet for the circulation of fluid, and a second section with a first inlet and a second inlet for the circulation of fluid,

   - a secondary low-temperature cooling circuit comprising a low-temperature loop equipped with a secondary low-temperature radiator and with means for circulating a low-temperature cooling liquid, and

   - interconnection means connecting the main circuit and the secondary circuit, the said interconnection means making it possible to integrate the two sections of the main radiator into the main circuit or to integrate the first section into the main circuit and the second section into the secondary circuit,

   characterized in that

   - the first inlet (21a, 121a, 221a) and the second inlet (21b, 121b, 221b) of the first section (21, 121, 221) of the main radiator (2) are respectively connected to a first main radiator pipe (112) and a second main radiator pipe (113) of the high-temperature loop (11), the first inlet (22a, 122a, 222a) of the second section (22, 122, 222) being connected to the low-temperature loop (31), and connected to the first inlet of the first section by fluid communication means (27, 127, 227),

   - the said interconnection means comprising a four-way valve system (4) connected by a first port (41) to the second main radiator pipe (113), by a second port (42) to the second inlet (22b, 122b, 222b) of the second section of the main radiator, and interposed on the low-temperature loop by a third port (43) and a fourth port (44),

   - the said four-way valve system being able

   - to bring into communication, on the one hand, the first port (41) and the second port (42) and, on the other hand, the third port (43) and fourth port (44) in order to separate the main circuit (1) and the secondary circuit (3) by integrating the first and the second sections of the main radiator into the high-temperature loop during an operation in normal mode at high speed and load,

   - to bring into communication the third port and the second port in order to integrate the second section of the main radiator into the low-temperature loop during an operation in normal mode at moderate speed and load, with enhanced cooling of the secondary circuit, and

   - to bring into communication the third port with the first port and the second port in order to integrate the second section and at least in part the first section of the main radiator into the low-temperature loop during an operation in normal mode at moderate speed and load, with greatly enhanced cooling of the secondary circuit.
2. Thermal management device according to Claim 1, characterized in that the valve system (4) is able to bring the first port (41) into communication with the second and third ports (42, 43) in order to cool the heat engine (9) using the secondary radiator (32) during an operating mode in degraded mode.
3. Thermal management device according to Claim 1 or 2, characterized in that the valve system (4) is able to bring the first port (41) and the third port (43) into communication in order to cool the engine (9) when stopping the engine while hot during an operation in engine cooling mode.
4. Thermal management device according to one of Claims 1 to 3, characterized in that the main circuit (1) comprises a main thermostat (17) on the first main radiator pipe (112) in order to cut or allow the circulation of fluid in the direction of the main radiator (2).
5. Thermal management device according to Claim 4, characterized in that it comprises a bypass pipe (18) connecting the first main radiator pipe (112), upstream of the main thermostat (17), to a heat recovery thermostat (5), mounted on the pipe (38) which connects the first inlet (22a) of the second section (22) to the low-temperature loop (31), the said thermostat bringing either the second section (22) into communication with the low-temperature loop, for the said operations in degraded mode and in normal mode with enhanced and greatly enhanced cooling, or the bypass pipe into communication with the low-temperature loop for the recovery of heat energy during an operation in cold start mode and/or cabin heating mode when the engine is stopped, during which operation the valve system (4) brings the first port (41) and the third port (43) into communication.
6. Thermal management device according to one of Claims 1 to 5, characterized in that the low-temperature loop (31) comprises a pipe (37) bypassing the low-temperature radiator that is connected upstream of the secondary radiator (32) to a heat recovery thermostat (36).
7. Thermal management device according to one of Claims 1 to 6, characterized in that the said valve system comprises four controlled two-way valves: a first valve (45) connecting the first and third ports (41, 43), a second valve (46) connecting the second and third ports (42, 43), a third valve (47) connecting the first and second ports (41, 42), and a fourth valve (48) connecting the third and fourth ports (43, 44).
8. Thermal management device according to one of Claims 1 to 7, characterized in that the main radiator (2) is formed by a single heat exchanger with a first and a second header box (23, 24; 123, 124), the first and the second sections (21, 22; 121, 122) being defined by a sealed partition (26, 126) and a honeycomb partition (27, 127) respectively positioned in the first and the second header boxes, the said honeycomb partition constituting the said fluid communication means.
9. Thermal management device according to one of Claims 1 to 8, characterized in that the low-temperature loop (31) incorporates a charge-air/liquid radiator, termed CAR radiator (34, 134), and a recirculated exhaust gas/liquid radiator, termed EGR radiator (35, 135).
10. Thermal management device according to Claim 9, characterized in that the EGR radiator (135) and/or the CAR radiator (134) comprise, from upstream to downstream with respect to the gas flows passing through them, at least one high-temperature portion, connected to the main circuit (1), and one low-temperature portion connected to the secondary circuit (3) in order to provide cooling at two temperature levels for the said gas flows.

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