WO2010012919A1 - Supercharged internal combustion engine provided with a flexible exhaust gas recirculation circuit and method for operating the engine - Google Patents

Abstract

The invention relates to a supercharged internal combustion engine particularly including an exhaust gas recirculation circuit (5) provided with a third duct (5.3) for feeding fresh air from the intake circuit (2) into the recirculation circuit (5), as well as an auxiliary compressor (5.4) compressing the fresh air and/or exhaust gases before the insertion thereof into the intake circuit (2). The corresponding ducts (5.1, 5.2, 5.3) as well as the intake duct (2) are provided with flow-rate control means (2.1) so as to control the amounts of fresh air and/or gases flowing respectively in the recirculation circuit (5) and in the intake circuit (2).

Description

 Supercharged internal combustion engine equipped with a flexible exhaust gas recirculation circuit and method of operating the engine

The present invention relates to a supercharged internal combustion engine comprising at least one combustion chamber, an air intake circuit and / or gases audited combustion chambers, a fuel introduction circuit in said combustion chambers. , an exhaust gas system produced during the combustion of the mixture of fuel and air and / or gases in said chambers, a turbocharger with a turbine and a main compressor, said turbine being located along the circuit of exhaust and driving the compressor, the latter being located along the intake circuit and compressing the air before admission to the combustion chambers, and an exhaust gas recirculation circuit comprising a first conduit serving as input and being connected to the exhaust circuit so as to introduce gases from the exhaust system to the recirculation circuit and a second exhaust duct e and being connected at one end to the first conduit and at the other end, downstream of said compressor, to the intake circuit so as to reintroduce the gases from the exhaust system. The invention also relates to a land vehicle equipped with such a motor and a method of actuating such a motor. Generally, the object of the present invention relates to internal combustion engines and particularly to diesel engines which, on the one hand, are supercharged and, on the other hand, have a recirculation of exhaust gases.

The supercharging of an internal combustion engine serves to increase its efficiency and is normally provided by a turbocharger. It consists of a turbine and a compressor to increase the amount of air admitted into the combustion chambers formed by the engine cylinders. Typically, the turbine is placed at the outlet of the exhaust manifold of the engine and is driven by exhaust gases. The power provided by the exhaust gases to the turbine can either be modulated, for example by installing movable fins, this being known as variable geometry turbo, or be constant, for example by using a proportional bypass terminals of the turbine, which is known as turbo constant geometry. The compressor is generally mounted on the same axis as the turbine and is placed at the inlet of the intake manifold, so as to compress the air supplied to the engine cylinders. The boost pressure setpoint is normally calculated by a calculation unit and the effective pressure is measured via a pressure sensor placed on the intake manifold. In addition, a charge air cooler can be placed between the compressor and the intake manifold to control the temperature of the air at the outlet of the compressor. On the other hand, a supercharged diesel engine often has the disadvantage of a gap in terms of takeoff brio. This problem is called "turbo lag" and appears when the vehicle engages an acceleration phase. The turbocharger indeed requires a time of the order of a few seconds to deliver a sufficient boost pressure during which the amount of fuel required for acceleration can not be burned due to the lack of a corresponding amount of air.

Such a supercharged engine may be equipped with exhaust gas recirculation in order to reduce the pollution generated by the engine, especially with regard to the nitrogen oxides. In fact, the quantity of nitrogen oxides emitted, for example in the case of a diesel engine, is strongly related to the composition of the reaction mixture in the engine cylinders in air, in fuel and the presence of inert gases. . A principle known to those skilled in the art as "exhaust gas recirculation" (EGR / exhaust gas recirculation) and of diverting a portion of the exhaust gases to the engine intake circuit allows to reduce in in addition to these emissions of nitrogen oxides, but it may increase the smoke if the rate of EGR is too high. The EGR can be realized by putting the exhaust circuit and the intake circuit in communication via a passage section whose dimension is adjustable by a valve corresponding in the recirculation circuit. Exhaust gases are, in currently known architectures, often recycled downstream of said charge air cooler. The dilution of fresh air with the exhaust gases thus produced effectively limits the maximum combustion temperatures and the production of nitrogen oxides, but the arrival of hot gases by the recirculation circuit also entails the disadvantage to increase the temperature in the intake manifold, which limits the efficiency of the reduction of nitrogen oxides. On the other hand, when a large amount of exhaust gases conventionally taken upstream of the turbine is recycled, the energy available to the turbine is reduced, so the fresh air flow procured by the compressor. As a result, particulate emissions increase, which limits the potential for reducing nitrogen oxides and is often unacceptable for the current legal standards for clean-up.

In order to solve the above-mentioned turbo lag problem, WO 2006/136790 proposes to position, downstream of the EGR system, an electric compressor intended to supply energy to the gas mixture before it enters the intake manifold. This has the advantage of making it possible to increase the speed of increase in pressure of the supercharging independently of the turbocharger and consequently to increase the flow rate of fresh air and exhaust gases, in particular for the purposes of depollution. However, the electric compressor, even deactivated, remains in the intake circuit and generates significant pressure losses, which can penalize the maximum performance of the engine. Furthermore, it is generally clear that there are several types of different phases during the operation of an engine, especially if it is used for driving a vehicle, these operating phases being able to require a different supply of fresh air, exhaust gases and fuel. Therefore, it would be desirable to have a motor with a sufficiently flexible architecture to meet these varying needs. Thus, despite the advantages provided by the principles of supercharging and recirculation of exhaust gases in the context of a supercharged engine, the current architectures of such engines still have several disadvantages. The object of the present invention is to at least partially overcome these disadvantages and to propose a supercharged internal combustion engine equipped with exhaust gas recirculation which has a flexible architecture adapted to a large number of different phases. engine operation, this using simple and inexpensive technical means, also to counter the problems caused turbo lag and engine pollution.

The present invention proposes for this purpose a supercharged engine that is distinguished in particular by the fact that the exhaust gas recirculation circuit comprises a third conduit for bringing into the recirculation circuit fresh air from the circuit of intake and an auxiliary compressor compressing fresh air and / or exhaust gases before their introduction into the intake circuit, the first -, the second - and the third duct and the intake duct being equipped a first -, a second - and a third - respectively a fourth means for controlling the flow and / or switching of the flow so as to allow the fresh air quantities and / or gases circulating in the recirculation circuit respectively in the intake circuit and direct the flow in these circuits. Thus, it becomes possible to improve such a supercharged engine, particularly thanks to the fact that the intake and exhaust gas recirculation circuits can be used in a flexible manner to guide the flow of air and / or gases in one or the other of these circuits according to the needs according to the operating phase in which the engine is located.

According to a preferred embodiment of the engine, the intake circuit comprises, between the connections to said third conduit and said second conduit, a first cooling means comprising at least two circulation branches. In this case, said second conduit serving as an output of the recirculation circuit is connected to the output of said first cooling means via the second means for controlling the flow and / or switching of the flow so that, depending of the position of said flow control and / or flow switching means, gases from the exhaust circuit and / or fresh air are introduced to the intake circuit either by passing through the first cooling means or by shorting it. This arrangement adds the additional possibility of being able to first cool the fresh air and / or the re-circulated exhaust gases or introduce them directly to the intake manifold. In addition, in the case where the flow of air and / or gases is oriented in the charge air cooler, the residence time can be extended thanks to the presence of two branches in the cooler, one of which is traversed by the flow in contradiction. In addition, the first conduit of the recirculation circuit may comprise a second cooling means equipped with a bypass, thus also shorting this cooler.

Preferably, the auxiliary compressor is controlled by an electric motor, and the first - and the third flow control and / or flow-switching control means are made by a control valve or an intake valve respectively, and the second - and the fourth means for controlling the flow and / or switching of the flow by an inlet valve or an input switching valve.

It is obvious that the engine may consist of a supercharged diesel engine and that the invention also relates to a land vehicle comprising an engine according to the present invention.

The subject of the invention is also a method of actuating such an engine which comprises, in order to obtain optimum engine performance, the steps of closing the first means of controlling the flow and / or switching of the engine. flow, to open the second flow control and / or flow switching control means, to close the third flow control and / or flow switching means, to open the fourth flow control means and / or switching the flow, and stop the auxiliary compressor. In other phases of operation of the engine, for example in order to obtain a rapid take-off of the engine, in order to obtain a high temperature recirculation operation, in order to obtain a recirculation operation at low temperature, in order to to obtain an optimal depollution, or in order to obtain a regeneration of a particulate filter located in the exhaust circuit, the flow control and / or flow-switching control means and the auxiliary compressor are correspondingly managed, thus making it possible to guarantee a physical constellation of the intake circuit and of the recirculation circuit that is optimally adapted to each of these situations, thereby improving the overall operation of the supercharging and the result of the depollution. Other advantages emerge from the features expressed in the dependent claims and from the description which sets forth the invention in more detail with the aid of drawings.

The accompanying drawings illustrate, schematically and by way of example, several embodiments of the invention.

FIG. 1a shows a schematic diagram of a supercharged internal combustion engine equipped with an exhaust gas recirculation according to the present invention, this figure presenting at the same time a constellation of means for controlling the flow and / or switching of the flow as well as the auxiliary compressor during an engine operating phase to obtain optimum performance of the engine; Figure 1b shows in detail the cooling means installed on the recirculation circuit. FIG. 2 shows a constellation of flow control and / or flow switching control means as well as the auxiliary compressor during an engine operating phase which makes it possible to obtain a rapid take-off of the engine.

FIG. 3 shows a constellation of flow control and / or flow switching control means as well as the auxiliary compressor during an engine operating phase enabling high temperature recirculation.

FIG. 4 shows a constellation of flow control and / or flow switching control means as well as the auxiliary compressor during an operating phase of the engine enabling recirculation at low temperature. FIG. 5 shows a constellation of flow control and / or flow switching control means as well as the auxiliary compressor during an engine operation phase enabling optimal depollution to be obtained.

FIG. 6 shows a constellation of flow control and / or flow switching control means as well as auxiliary compressor during an engine operating phase which makes it possible to obtain a regeneration of a particle filter located in the circuit of FIG. 'exhaust.

The invention will now be described in detail with reference to the accompanying drawings which will illustrate, by way of example, several embodiments of a supercharged engine according to the present invention.

In order to turn to the structure of an engine according to the present invention, Fig. 1a shows a block diagram of a supercharged internal combustion engine and equipped with recirculation of exhaust gases according to this invention. Such an internal combustion engine comprises at least one combustion chamber which is indicated in FIG. 1 a symbolically by cylinders 1, the number of which is not important for the present invention. In addition, it comprises an air intake circuit and / or gases 2 said combustion chambers 1, a fuel introduction circuit in said combustion chambers 1, this circuit not being shown in the figures, and a circuit exhaust gases 3 produced during the combustion of the mixture of fuel and air and / or gases in said chambers 1. Along the air intake circuit and / or gases 2 may, in addition, there are usual elements such as an air filter, a flow meter and a first cooling means 2.2, before the intake circuit ends with the intake manifold whose branches open into the cylinders 1 of the engine. After combustion, the exhaust gases first enter an exhaust manifold whose branches meet in a conduit that leads them, often after passing through a particulate filter, especially in the case of an engine diesel, to the outlet, these elements forming a gas exhaust circuit 3.

The engine according to the present invention further comprises a turbocharger 4 with a turbine 4.1 and a main compressor 4.2. Said turbine 4.1 is located along the exhaust circuit 3, generally in the high pressure zone upstream of the particulate filter, in order to be driven by the exhaust gases so as to be able to supply energy to the compressor main 4.2. This compressor 4.2 is located along the intake circuit 2 and is preferably mounted on the same axis as the turbine 4.1, so as to compress the air and / or the gases before their admission to the combustion chambers 1. As already mentioned in the introduction, several types of turbochargers, for example with variable or constant geometry, can be chosen indifferently with respect to the present invention.

Then, the engine according to the present invention further comprises an exhaust gas recirculation circuit 5 which comprises a first duct 5.1 serving as a gas inlet and being connected at one of its ends, upstream of said turbine 4.1, to the exhaust circuit 3 so as to introduce to the recirculation circuit 5 gases from the exhaust circuit 3. The other end of the first conduit 5.1 is connected to a second conduit 5.2 serving as a gas outlet, it is that is, the second conduit 5.2 is connected at one end to the first duct 5.1 and at the other end to the intake circuit 2, downstream of said compressor 4.2, so as to reintroduce to the intake circuit 2 gases from the exhaust circuit 3.

In particular, the exhaust gas recirculation circuit 5 of an engine according to the present invention also comprises a third duct 5.3 for supplying fresh air from the intake circuit 2 directly into the recirculation circuit 5. and an auxiliary compressor 5.4 compressing the fresh air and / or the exhaust gases before their introduction into the intake circuit 2. Preferably, said auxiliary compressor 5.4 is located between the first -

5.1 and the second conduit 5.2 of the recirculation circuit 5 and is controlled by an electric motor or other equivalent means and independent of the turbocharger 4. Thus, the auxiliary compressor 5.4 can compress the fresh air and / or exhaust gases circulating in the exhaust circuit 5 and provide a compressed flow to the intake circuit 2 independently of the turbocharger 4 respectively the engine speed.

With regard to said third duct 5.3 of the recirculation circuit 5, it is preferably connected to an end serving as a fresh air inlet to the intake circuit 2, between said main compressor 4.2 and said second duct 5.2, and at the other end serving as a fresh air outlet to the recirculation circuit 5, upstream of said auxiliary compressor 5.4, that is to say with the first conduit 5.1 of the recirculation circuit 5. The recirculation of gas from Exhaust as illustrated in Figure 1 thus performs a reintegration of exhaust gases from the upstream of the turbine 4.1 in the downstream of the compressor 4.2, with an introduction of fresh air also from the downstream of the compressor 4.2, but from the upstream of the connection of the second conduit 5.2 to the intake circuit 2, in the recirculation circuit 5. Other connection variants according to the spirit of the present invention are also within the scope of the invention. skilled person. In general, it is a recirculation of exhaust gases with introduction of fresh air, this to high pressure, since the circuit 5 is entirely upstream of the turbine

4.1 respectively downstream of the compressor 4.2, that is to say on the side of the supercharging of the engine at high pressure.

Furthermore, the present invention proposes that the first - 5.1, the second - 5.2 and the third duct 5.3 of the exhaust gas recirculation circuit 5 as well as the intake duct 2 comprise a first - 5.1.1, a second - 5.2.1 and a third - 5.3.1 respectively a fourth flow control and / or flow switching control means 2.1 so as to allow to control the quantities of fresh air and / or gases circulating in the recirculation circuit 5 respectively in the intake circuit 2 and direct the flow in these circuits according to the state of these means. The terms control means or switching means will in the following be used indifferently to designate such a flow control control means and / or flow switching, unless another meaning is specified explicitly. Such an arrangement makes it possible for the intake and exhaust gas recirculation circuits 5 to be used in a simple and flexible manner to orient a variable and controllable flow of air and / or exhaust gases in one or in the other of these circuits according to the needs according to the operating phase in which the engine is at a given moment, which will be explained in detail in the following description.

In a preferred embodiment of an engine according to the present invention, the intake circuit 2 comprises a first cooling means

2.2 located between the connections of the intake circuit 2 to said third conduit 5.3 and said second conduit 5.2. The role of this cooling means of reducing the temperature of the inlet gases and, consequently, the combustion temperature, resulting in a reduction of nitrogen oxide emissions, is conventional. This first cooling means 2.2 of an engine according to the present invention has the particularity of comprising at least two traffic branches 2.2.1, 2.2.2. In addition, said second conduit 5.2 serving In this case, the output of the recirculation circuit 5 is connected to the output of this first cooling means 2.2 via the second switching means 5.2.1 so that, depending on the position of said switching means 5.2 .1, gases from the exhaust circuit 3 and / or fresh air are introduced to the intake circuit 2 either by passing through the first cooling means 2.2 or directly to the intake manifold by shorting the first cooling means 2.2. This arrangement of the intake and recirculation circuits 2 adds the additional possibility of first being able to cool the fresh air and / or the recirculated exhaust gases which in this case traverse the second branch 2.2.2 in reverse and the first branch 2.2.1 in the normal direction of circulation or introduce them directly to the intake manifold. In addition, in the case where the flow of air and / or gases is oriented in the charge air cooler 2.2, the residence time can be extended thanks to the presence of two branches 2.2.1, 2.2.2 in the cooler, one of which is traversed in the opposite direction by the flow as mentioned above.

Indeed, the first - and the third flow control and / or flow-switching control means are preferably carried out by a control valve 5.1.1 or an intake valve 5.3.1 respectively, these valves allowing at the same time time to control the flow through the respective ducts and, by closing or opening, to direct the flow in one or another conduit. The second - and the fourth flow control and / or flow-switching control means are, for reasons of simplicity and costs, preferably provided by an inlet valve 5.2.1 or a switching valve respectively. input 2.1, thus allowing switching of the flow according to the position of the valve concerned, as will be described in more detail below. Advantageously, the inlet valve 5.2.1 and the input switching valve 2.1 can also be positioned respectively at the outlet and at the inlet of said first cooling means 2.2, in particular the inlet valve 5.2. .1 so as to allow such cooperation with the second branch 2.2.2 of the cooler. Of course, it would be possible to arrange the means 5.1.1, 5.2.1, 5.3.1, 2.1 so that they all have the functionality to vary the flow and to be able to switch the flow.

It should also be noted that the first conduit 5.1 of the recirculation circuit 5 normally comprises a second cooling means 5.1.2 which makes it possible to regulate the temperature of the gases circulating in this conduit and which is preferably equipped with a bypass, as shown schematically in FIG. 1b. The bypass comprises a bypass valve, and the control valve 5.1.1 placed in the first conduit 5.1 may be located upstream or downstream of the cooler-by-pass system, as is also apparent from FIG. 1 b. Other elements usually used in this kind of engine may also be present in the circuits 2, 3, 5 without having any importance in the context of the present invention. In addition, the implementation of a slice of oxidation catalyst upstream of the EGR system could be useful to limit the recirculation of unburned hydrocarbons.

Furthermore, it is clear that the engine according to the present invention can be a supercharged diesel engine or any other type of engine of this kind, and that the invention also relates to a land vehicle comprising a motor as described above. The operation of such an engine can be best understood by describing the method of operating an engine according to the present invention. For this purpose, FIG. 1a shows, next to the general structure of such an engine, a constellation of flow control and / or flow switching control means as well as auxiliary compressor during an operating phase of the engine to achieve optimum engine performance. As is apparent from FIG. 1a, in this mode of operation of the engine, the first flow control and / or flow switching control means, the control valve 5.1.1 of the exhaust gas recirculation, is closed. , such as the third flow control and / or flow switching control means, the air intake valve 5.3.1, while the second flow control and / or flow switching control means, the fresh air and / or exhaust gas inlet valve 5.2.1 as well as the fourth flow control and / or flow switching, switching valve 2.1 of the air inlet are open. The completely open state of these control means is symbolized in the figures by the number 1 surrounded by a circle, the state closed by the digit 0 surrounded by a circle, and the partially open state respectively partially closed by Vi surrounded by a circle. Furthermore, the auxiliary compressor 5.4 is stopped in this mode of operation of the engine, symbolized in Figure 1a by the word off surrounded by a circle. Thus, the EGR system is deactivated, such as the introduction of air into the recirculation circuit 5, so that neither exhaust gases burned nor fresh air can circulate in the EGR circuit 5. The turbine 4.1 placed in the exhaust circuit 3 is therefore driven at full power by the exhaust gases that exit only through this circuit 3. The main compressor 4.2 compresses the fresh air that passes only through the intake circuit 2 and the feeds directly back into the aftercooler 2.2 where the air temperature is lowered and the whole volume of which is used, that is to say the two branches 2.2.1, 2.2.2 in the same direction of circulation, this which reduces the pressure drops. In the figures, the directions of the flow of fresh air respectively of exhaust gases in the circuits 2, 3, 5 are indicated symbolically by arrows. Therefore, in this mode of operation, the density of air in the intake manifold is maximum, allowing the best use of engine performance.

In order to solve the turbo lag problem mentioned in the introduction, the present invention makes it possible to activate the engine in another mode of operation so as to obtain a rapid take-off of the engine. As illustrated diagrammatically in FIG. 2, the corresponding method of actuating the engine comprises the steps of closing the control valve 5.1.1, closing the inlet valve 5.2.1 with fresh air and / or heating gases. exhaust, to fully open the air intake valve 5.3.1, and to close the switch flap 2.1 of the air intake, this by switching on the auxiliary compressor 5.4. By these measures, it is possible to provide as quickly as possible a large fresh air flow to the engine, because the first conduit 5.1 of the recirculation circuit 5 is closed and the inlet valve is completely open, thus allowing the electric compressor 5.4 transmits energy to the fresh air flowing in the third - 5.3, then the second duct 5.2 of the recirculation circuit 5 and initially weakly compressed by the main compressor 4.2. The air is then sent to the charge-air cooler 2.2, passing through its two branches 2.2.1, 2.2.2 in opposite traffic directions and having an extended residence time with respect to a normal course, that is to say in the same direction of circulation in both branches. Therefore, the engine takes advantage of the accelerated arrival of fresh air flow and then releases more energy to the exhaust, which promotes the speed up of the turbocharger 4. The electric compressor 5.4 can be stopped when the compressor main 4.2 is able to provide the boost pressure requested by the driver of the vehicle. This operating mode shows in particular that the second means of controlling the flow preferably carried out by a fresh air introduction valve 5.2.1 and / or exhaust gases makes it possible in particular to manage the use of the second branch 2.2. .2 of the first cooling means 2.2 as well as short-circuiting the latter. Thus, this mode of operation of the engine reduces the response time of the engine at takeoff.

In yet another mode of operation of the engine, it is possible to obtain recirculation of exhaust gases and fresh air at high temperature. The corresponding method of actuating the engine comprises, as shown schematically in FIG. 3, the steps of partially opening the control valve 5.1.1, opening the fresh air introduction valve 5.2.1 and / or exhaust gases, to completely open the intake valve 5.3.1 of air, and to close the switching valve 2.1 of the air intake, this by stopping the auxiliary compressor 5.4. In this constellation, the control valve 5.1.1 and the intake valve 5.3.1 being respectively partially and fully open, a mixture of fresh air and recycled gases is in the recirculation circuit 5. The mixture passes through the electric compressor off and does not circulate in the charge-air cooler 2.2, since the flap 5.2.1 is in its bypass position of the cooler. The mixture of fresh air and recycled gauze thus arrives at high temperature in the intake manifold, a situation that is sought for an optimal depollution when the engine is still cold, that is to say when it is still at the temperature cooling water.

In a similar constellation and shown in FIG. 4, but intended to achieve low temperature recirculation operation, the activation method according to the present invention comprises the steps of partially opening the control valve 5.1.1, close the fresh air and / or exhaust gas inlet valve 5.2.1, fully open the air inlet valve 5.3.1, close the air inlet valve 2.1 air and stop the auxiliary compressor 5.4. By difference to the previous constellation, the mixture of fresh air and exhaust gases in this case traverses the two branches 2.2.1, 2.2.2 of the cooler 2.2. This extends the residence time inside, reducing the intake temperature and therefore combustion to further reduce emissions of nitrogen oxides when the engine is hot.

In another mode of operation of the engine shown by a block diagram in Figure 5, it is possible to obtain a maximum depollution. The corresponding method comprises the steps of fully opening the control valve 5.1.1, closing the inlet valve 5.2.1 fresh air and / or exhaust gases, to fully open the inlet valve 5.3.1 of the air, close the switching valve 2.1 of the air inlet and switch on the auxiliary compressor 5.4. This mode of operation is intended to further increase the amount of recycled gas while preserving or even increasing the flow of fresh air. Compared with the previous constellation, the valve of control 5.1.1 and starts the auxiliary compressor 5.4. Thus, the fresh air is pre-compressed by the main compressor 4.2 and mixed with the recycled gases downstream of the air intake valve 5.3.1. The gaseous mixture is then sent to the activated electric compressor 5.4 which brings an additional amount of energy to the assembly and simultaneously increases the flow rates of air and exhaust gases. The mixture travels through the two branches 2.2.1, 2.2.2 of the cooler 2.2, which lengthens the residence time and promotes the cooling of the mixture. The mixture of air and exhaust gases thus arrives at the intake manifold under better conditions for the depollution. Indeed, because the combustion temperature is reduced and the flow rates of air and exhaust gases are high, emissions of nitrogen oxides are lower and the unburned particulate wealth remains limited.

In order to obtain, for example, a regeneration of a particle filter located in the exhaust circuit, an engine according to the present invention can be further actuated by a method which comprises the steps of closing the control valve 5.1.1. , to open the inlet valve 5.2.1 fresh air and / or exhaust gases, to partially open the air intake valve 5.3.1, to close the switch valve 2.1 of the air intake, and stop the auxiliary compressor 5.4. This configuration shown in Figure 6 is the opposite of the operating mode of the engine with maximum performance. In the present case, the efficiency of post-treatment purges, such as in particular the regeneration of a particle filter located along the exhaust circuit 3 or the sulfur purge, is obtained by means of an increase in the temperature and the particle richness of the exhaust gases. By closing the first duct 5.1 of the recirculation circuit 5 and limiting the air flow downstream of the turbocharger through intake valve 5.3.1 air, only air passes through the electric compressor 5.4 extinguished and is not cooled, passing directly into the intake manifold of the intake circuit 2. It is thus possible to reduce the density of the air in the intake manifold and the gases exhaust exhaust at the engine outlet are hotter and richer in particles, which can, for example, promote at a lower cost the regeneration of a particulate filter possibly located on the exhaust line 3.

It should be noted that a motor without an auxiliary compressor can be used in the same way as an engine equipped with such an auxiliary compressor and operating in one of the modes of operation described above with this compressor off .

In view of the above description of an engine according to the present invention as well as methods of putting it into action, its advantages are clear, in particular that the present invention proposes an architecture of a motor made with simple means and relatively inexpensive, but flexibly allowing different modes of operation of the engine adapted to particular situations during its operation, especially when the engine serves as a driving means in a land vehicle such as a car. An engine according to the present invention has in particular the advantages associated with the many possible flow orientation constellations, furthermore that the intake valve 5.3.1 of air in cooperation with the switching valve 2.1 of the inlet of air allows either to force the air flow in the recirculation circuit 5 comprising the electric compressor 5.4 or by-pass thereof, thus avoiding the loss of pressure due to this compressor when it is not used, since the introduction valve 5.2.1 fresh air and / or exhaust gases allows to choose the path of the flow through the supercharger 2.2, adding the ability to influence the air temperature and gauze, and that the control valve 5.1.1 and the air intake valve 5.3.1 allow to control the composition of the mixture of fresh air and exhaust gases flowing through the recirculation circuit 5, influenced by thus an important parameter for engine depollution. Furthermore, the invention also provides at least a partial solution to the aforementioned problems of turbo lag and the depollution of an engine, in particular a diesel engine, as is apparent from the description above.

In addition, the invention proposes a solution that can be used to dispense with a particulate filter to treat the exhaust gases while limiting the fouling of the intake circuit, this by immediately diluting the gases passing through the EGR system. in the fresh air, which reduces the concentration of particles and therefore their tendency to agglomerate, and by using the electric compressor 5.4, whose blade material can be chosen to withstand the impact of particles having characteristics close to those conventionally used on a turbine wheel. Indeed, due to its regular activity, the electric compressor 5.4 is a dynamic component and, because of the elimination of deposits by centrifugation, favors less particle deposition than a valve which is a quasi-static element. Furthermore, the fact of having in some modes of operation of the engine an alternate direction of circulation in the second branch 2.2.2 of the supercharger 2.2, which is its most exposed part at the arrival of the gases of Exhaust from the recirculation circuit, allows, in the mode of operation at maximum performance, that the fresh air scans the deposited particles and then burn them in the engine, this mode thus simultaneously performing a cleaning of the charge cooler. Finally, the invention allows a better use of the charge cooler 2.2, in the sense that, for the same volume, the U-shaped circulation in the cooler provides the gas mixture longer residence time, which has the effect of reducing the temperature of the gases at the inlet and thus improve the efficiency as well as reduce emissions of nitrogen oxides.

Claims

Claims

1. Supercharged internal combustion engine comprising at least one combustion chamber (1), an air and/or gas admission circuit (2) to said combustion chambers, a fuel introduction circuit into said combustion chambers combustion, a gas exhaust circuit (3) produced during the combustion of the mixture of fuel and air and/or gases in said chambers (1), a turbocharger (4) with a turbine (4.1) and a main compressor (4.2), said turbine (4.1) being located along the exhaust circuit (3) and driving the compressor (4.2), the latter (4.2) being located along the intake circuit (2) and compressing the air before its admission to the combustion chambers, as well as an exhaust gas recirculation circuit (5) comprising a first conduit (5.1) serving as an inlet and being connected to the exhaust circuit (2) of so as to introduce into the recirculation circuit (5) gases coming from the exhaust circuit (3) as well as a second conduit (5.2) serving as an outlet and being connected at one end to the first conduit (5.1) and at the other end, downstream of said compressor (4.2), to the intake circuit (2) so as to reintroduce the gases from the exhaust circuit (3), characterized in that the exhaust gas recirculation circuit ( 5) comprises a third conduit (5.3) making it possible to bring fresh air coming from the intake circuit (2) into the recirculation circuit (5) as well as an auxiliary compressor (5.4) compressing the fresh air and /or the exhaust gases before their introduction into the intake circuit (2), the first - (5.1), the second - (5.2) and the third conduit

(5.3) as well as the intake conduit (2) being equipped with a first - (5.1.1), a second - (5.2.1) and a third - (5.3.1) respectively a fourth means of controlling the flow and/or switching the flow (2.1) so as to allow the quantities of fresh air and/or gases to be controlled circulating in the recirculation circuit (5) respectively in the admission circuit (2) and directing the flow in these circuits.

2. Engine according to the preceding claim, characterized in that said auxiliary compressor (5.4) is located between the first - (5.1) and the second conduit (5.2) of the recirculation circuit (5) and that said third conduit (5.3) of the recirculation circuit (5) is connected at one end serving as a fresh air inlet to the intake circuit (2), between said main compressor (4.2) and said second conduit (5.2), and at the other end serving as an outlet for the recirculation circuit (5), upstream of said auxiliary compressor (5.4).

3. Engine according to one of the preceding claims, characterized in that the intake circuit (2) comprises, between the connections to said third conduit (5.3) and said second conduit (5.2), a first cooling means (2.2 ) comprising at least two branches of circulation (2.2.1,

2.2.2).

4. Motor according to the preceding claim, characterized in that said second conduit (5.2) serving as an outlet of the recirculation circuit (5) is connected to the outlet of said first cooling means (2.2) via the second means of cooling. flow control and/or flow switching (5.2.1) so that, depending on the position of said flow control and/or flow switching means (5.2.1), gases coming from the circuit exhaust (3) and/or fresh air are introduced to the intake circuit (2) either by passing through the first cooling means (2.2) or by short-circuiting it.

5. Motor according to claim 2, characterized in that the first conduit

(5.1) of the recirculation circuit (5) comprises a second cooling means (5.1.2) equipped with a by-pass.

6. Engine according to one of the preceding claims, characterized in that the auxiliary compressor (5.4) is controlled by an electric motor.

7. Motor according to one of the preceding claims, characterized in that the first - and the third means of controlling the flow and/or switching the flow are produced by a control valve (5.1.1) respectively a valve d admission (5.3.1) and that the second - and the fourth means of controlling the flow and/or switching the flow are produced by an introduction valve (5.2.1) respectively an inlet switching valve (2.1 ).

8. Engine according to one of the preceding claims, characterized in that the engine is a supercharged diesel engine.

9. Land vehicle, characterized in that it comprises an engine according to one of the preceding claims.

10. Method for activating a motor according to one of the preceding claims 1 to 7, characterized in that, in order to obtain optimal performance of the motor, it comprises the steps of

- close the first flow control and/or flow switching means (5.1.1),

- open the second flow control and/or flow switching means (5.2.1),

- close the third means of flow control and/or flow switching (5.3.1), - open the fourth flow control and/or flow switching means (2.1), and

- stop the auxiliary compressor (5.4).

11. Method according to the preceding claim, characterized in that, in order to obtain rapid takeoff of the engine, it comprises the steps of

- close the first flow control means (5.1.1),

- close the second flow control means (5.2.1),

- open the third flow control means (5.3.1), - close the fourth flow control means (2.1), and

- start the auxiliary compressor (5.4).

12. Method according to one of preceding claims 10 to 11, characterized in that, in order to obtain operation of the recirculation at high temperature, it comprises the steps of

- partially open the first flow control means (5.1.1),

- open the second flow control means (5.2.1),

- open the third flow control means (5.3.1),

- close the fourth flow control means (2.1), and - stop the auxiliary compressor (5.4).

13. Method according to one of the preceding claims 10 to 12, characterized in that, in order to obtain operation of the recirculation at low temperature, it comprises the steps of - partially opening the first flow control means (5.1 .1),

- close the second flow control means (5.2.1),

- open the third flow control means (5.3.1),

- close the fourth flow control means (2.1), and

- stop the auxiliary compressor (5.4).

14. Method according to one of preceding claims 10 to 13, characterized in that, in order to obtain optimal depollution, it comprises the steps of

- open the first flow control means (5.1.1), - close the second flow control means (5.2.1),

- open the third flow control means (5.3.1),

- close the fourth flow control means (2.1), and

- start the auxiliary compressor (5.4).

15. Method according to one of preceding claims 10 to 14, characterized in that, in order to obtain regeneration of a particle filter located in the exhaust circuit, it comprises the steps of

- close the first flow control means (5.1.1),

- open the second flow control means (5.2.1), - partially open the third flow control means (5.3.1),

- close the fourth flow control means (2.1), and

- stop the auxiliary compressor (5.4).