FR2799503A1 - Engine unit for turbocharged motor vehicle with an exhaust catalyzer, uses recirculation of exhaust gas into the combustion chambers to remove oxides of nitrogen, extracts exhaust before it reaches the turbocharger - Google Patents

Abstract

The engine (12) has a turbocharger (18) in the exhaust line (16). Part of the exhaust gas is returned (48) to the engine inlet (14), with the gas drawn off (49) before it reaches the turbocharger turbine (24) and passes through a control valve (50) before reaching the inlet.

Description

The invention relates to a power train of a motor vehicle.

The invention more particularly relates to a motor vehicle powertrain comprising an internal combustion engine supercharged by a turbocharger, an air / fuel intake or mixture circuit and a flue gas exhaust system. comprise exhaust pipe which connects the exhaust of at least one combustion chamber of a cylinder, <B> to </ B> a turbocharger turbine with the interposition of a catalyst.

Internal combustion engines, including diesel engines as well as certain gasoline engines with spark ignition, produce exhaust fumes. The exhaust gases contain polluting and toxic substances such as oxides of nitrogen or NOx, carbon monoxide or <B> CO, </ B> unburned hydrocarbons or HC, which is necessary to treat.

When the internal combustion engine is supercharged by a turbocharger, the latter requires a pressure upstream of its turbine high enough for its training. It has thus been proposed to mount a turbocharger. oxidation catalyst downstream of the turbocharger turbine. However, during the passage of the exhaust gases in the turbine there is a transfer of energy decreases the temperature of the exhaust gas and when gas arrive in the catalyst, their temperature is lower <B> at </ B> the optimal operating temperature of the catalyst.

Patent VVO-A-92/20911 proposes to interpose the catalyst between the combustion chamber of an engine cylinder and the turbine of the turbocharger without disturbing the operation of the turbocharger. However, the catalyst makes it possible to oxidize carbon monoxide and unburned hydrocarbons, but does not make it possible to reduce the nitrogen oxides.

To reduce oxides of nitrogen while the exhaust gases are rich in oxygen, one method is to store the nitrogen oxides contained in the exhaust gas in a trap <B> to </ b>. </ B> NOx also called "Noxtrap" and <B> to </ B> periodically treat so trapped NOx by massively injecting reducing substances such as fuel. Patent EP-B-0.560.991 describes such a NOx storage device and different regeneration strategies.

This solution is complex. <B> It is necessary to insert a large NOx <B> trap at the upstream of the turbine, which causes additional and reduced pressure drop. thus the efficiency of the turbocharger, In addition, the regeneration of the trap <B> to </ B> may require the installation of fuel injection system. In addition to the installation of these ispositives in the exhaust, the re-settling phases of the trap are expensive in fuel.

In order to remedy these disadvantages the invention proposes a powertrain of the type described above, characterized in that a recirculation line connects a point of the exhaust pipe to the intake circuit. , so <B> to </ B> allow the recirculation of the exhaust gas into the combustion chamber of at least one cylinder.

According to other characteristics of the invention, the point of the exhaust pipe is located downstream of the catalyst and upstream of the turbine. <B> <B> << / B> recirculation line comprises means for regulating the flow of the exhaust gas <B>; </ B> <B> - </ B> recirculation line comprises means for cooling the exhaust gas <B>; < / B> <B> - </ B> the exhaust gas cooling means comprise a heat exchanger <B>; </ B> <B> - </ B> engine comprises several combustion chambers, in each chamber of combustion is connected <B> to </ B> at least one associated conduit of an exhaust manifold in which is interposed a catalyst, and in that the associated ducts meet in at least one exhaust pipe upstream of the turbine <B>; </ B> <B> - </ B> each combustion chamber has at least one exhaust valve, in that each exhaust valve is connected <B> to </ B> an exhaust pipe In this case, the associated exhaust ducts join a single exhaust duct upstream of the turbine. air cooling is interposed in the intake circuit between the downstream of the compressor of the turbocharger and the upstream of the engine.

Other characteristics and advantages will become apparent when reading the detailed description which follows for the understanding of which reference will be made to the appended drawings in which <B>: </ B> <B> - </ B> Figure <B> 1 </ B> represents a turbocharged supercharged power unit according to the state of the art <B>; </ B> Figure 2 represents a powertrain similar to that of Figure <B> 1 </ B> to which is added an exhaust gas recirculation circuit according to the invention <B>; </ B> <B> - </ B> <B> 3 </ B> represents a group similar power train <B> to </ B> that of Figure 2 with a heat exchanger interposed in the exhaust gas recirculation circuit <B>; </ B> and <B> - </ B> Figure 4 represents a similar booster group <B> to </ B> that of the previous figures, wherein a catalyst is disposed in each duct of the exhaust manifold.

Figure <B> 1 </ B> represents a supercharged powertrain <B> 10 </ B> according to the state of the art. is <B> composed </ B> primarily of an engine <B> to </ B> combustion of an intake circuit 14, an exhaust system <B> 16 </ B> and d a turbocharger <B> 18. </ B>

A filter <B> to </ B> air 20 is located upstream of the intake circuit 14 which retains the particles present in the fresh air from the atmosphere.

Turbocharger <B> 18 </ B> comprises a compressor 22 which is pressurized with fresh atmospheric air and a turbine 24 which supplies the necessary mechanical energy <B> to </ B> the drive of the compressor 22.

A cooling device <B> 26 </ B> is used to cool the intake air from the compressor 22.

Catalyst <B> 28 </ B> is interposed between the engine exhaust and turbocharger turbine 24 <B> 18. </ B> Powertrain operation <B> 10 </ B> depending on the state of the art is the next.

As the operation of the turbocharger is known to those skilled in the art, it will not be detailed in the following description.

Fresh air from the atmosphere is admitted into the intake circuit 14 after having passed through the filter <B> to </ B> air 20. <B> It </ B> is then sucked, then compressed by the compressor 22. The compression of the air causes its heating. The air is then cooled as it passes through the cooling device <B> 26. At the outlet of the latter an intake duct 40 conducts fresh compressed air into one or more combustion chambers of the engine.

After combustion, the <B> G </ B> exhaust gases contain nitrogen oxides, carbon monoxide and unburned hydrocarbons. They are discharged into an exhaust pipe 42 via exhaust manifold conduits 44.

The exhaust gases <B> G </ B> then enter the catalyst <B> 28. </ B> When the exhaust gases <B> G </ B> are oxidizing, which is particularly the case of <B> G </ B> exhaust from diesel engines and engines <B> to </ B> gasoline <B> to </ B> lean mixture, the catalyst <B> 28 </ B> causes mainly an oxidation. carbon monoxide and unburned hydrocarbons. These products are converted into less toxic and less polluting substances.

<B> At </ B> the catalyst outlet <B> 28, </ B> the exhaust gases are <B> at </ B> a higher pressure <B> at </ B> the atmospheric pressure. are then relaxed in the turbine 24. This trigger produces the mechanical energy that is transmitted by a shaft 46 to the compressor 22.

However, the exhaust gases <B> G </ B> released into the atmosphere are still loaded with nitrogen oxides.

The power unit <B> 10 </ B> according to the invention is shown <B> to </ B> in FIG. 2.

Elements similar or identical <B> to </ B> those of the state of the art are identified by the same references.

The powertrain <B> 10 </ B> allows, in addition to the significant reduction of emissions of carbon monoxide and unburned hydrocarbons in the exhaust gas <B> G, </ B> important decrease <B> d </ B > e the quantity of nitrogen oxides formed during the combustion of the fuel.

Nitrogen oxides are formed mainly, by reaction of nitrogen and oxygen present in the fresh air, in areas of the combustion chambers of the engine 12 in which the temperature is high and in which air / fuel ratio , or the richness of the mixture is close to <B> 1. </ B> The air / fuel ratio being fixed by the torque driver demand and by the operating point of the engine, it is necessary to reduce the combustion temperature in order to limit the formation of nitrogen oxides.

The invention consists of the interposition of a recirculation circuit 48 of the exhaust gas <B> G </ B> between the exhaust circuit and the intake circuit.

Exhaust gas recirculation <B> G </ B> is done in a natural way, thanks to <B> the </ B> the pressure difference exists between the exhaust system <B> 16 </ B> the intake circuit 14.

<B> It </ B> is therefore necessary to take the exhaust <B> G </ B> at a point 49 of the exhaust system <B> 16 </ B> where the pressure of the gases of exhaust <B> G </ B> is high, that is to say upstream of the turbine 24. They are then reintroduced into the intake circuit 14 downstream of the compressor 22.

A valve <B> 50 </ B> is mounted in the recirculation circuit 48 so as to <B> to </ B> regulate the flow of the exhaust gas <B> G </ B> flowing in the circuit 48 and which is intended to be mixed with fresh air of the intake circuit 14.

Indeed, some engine operating phase do not allow or little recirculation of exhaust gas <B> G. </ B>

A control system, not shown, manages the opening of the valve <B> 50. </ B> To do this, it takes into account the state of the various powertrain members <B> 10, < / B> including engine 12 and turbocharger <B> 18. </ B>

The exhaust gas recirculation allows the introduction of a quantity of exhaust gas into the fresh air circulating in the intake pipe 14, so as to reduce the formation of oxides of carbon dioxide. nitrogen during fuel combustion. This decrease is the consequence of the thermodynamic properties of the exhaust gases <B> G. </ B>

In fact, the main mechanism for the formation of nitrogen oxides is bound to the maximum combustion temperature and the formation of nitrogen oxides increases exponentially with the combustion temperature.

The presence of carbon dioxide strongly limits the combustion temperature and therefore the temperature of the exhaust gas <B> G. </ B>

Indeed, the heat capacity of carbon dioxide is much higher <B> than that of other products such as nitrogen and oxygen, which are mainly present in fresh air.

Therefore, for a given release of heat during the combustion of the fuel, the increase in temperature is even lower than the concentration of carbon dioxide in the air admitted into the combustion chamber is high.

However, the concentration of carbon dioxide is greater in the exhaust gases <B> G </ B> than in fresh air. Therefore, the amount of nitrogen oxides formed is greatly limited when using recirculation circuit 48.

Advantageously, the point 49 for sampling the exhaust gases <B> G </ B> in the exhaust system <B> 16 </ B> is located downstream of the catalyst <B> 28 </ B> and in upstream of the turbine 24.

This arrangement is very favorable in limiting the formation of nitrogen oxides during combustion. Indeed, the oxidation of carbon monoxide and unburned hydrocarbons in the catalyst <B> 28 </ B> produces a significant amount of carbon dioxide. Thus, exhaust gases <B> G </ B> flowing downstream of the catalyst have a higher concentration of carbon dioxide than exhaust gas <B> G </ B> flowing upstream of the catalyst. first variant shown <B> to </ B> Figure <B> 3, </ B> a heat exchanger <B> 52 </ B> interposed in the recirculation circuit 48. <B> It </ B> allows reduce the temperature of the exhaust gases <B> G </ B> which are mixed <B> with </ B> the fresh air which has the effect of decreasing the temperature of the air admitted into the combustion chambers of the motor 12 and, therefore, limit combustion temperature.

presence of cooling device <B> 26 </ B> which decreases temperature of fresh air that is heated by its passage in the compressor <B> 28 </ B> allows, similarly <B> to </ B> > the heat exchanger <B> 52, </ B> to limit the formation of nitrogen oxides decreasing the temperature of the fresh air admitted into the combustion chamber of the engine 12.

In a second variant, shown <B> to </ B> Figure 4, a catalyst <B> 28 </ B> is disposed in each conduit 43, the exhaust manifold 44, which is connected <B> to < / B> exhaust of a combustion chamber of the engine cylinder 12.

positioning <B> to </ B> proximity to the engine block allows it to benefit from an exhaust gas temperature that is higher than in the rest of the exhaust system <B> 16. </ B>

Thus, the catalysts <B> 28 </ B> are traversed by exhaust pipes <B> G </ B> which are <B> at </ B> a temperature closer to the optimum operating temperature of the catalyst, this makes it possible to improve their overall efficiency, and thus to reduce the dimensions thereof, and thus the bulk, while maintaining the same efficiency.

moreover, the temperature rise of the catalyst <B> 28 </ B> accelerated, which consequently accelerates its actuation thus reduces the quantity of carbon oxides and unburned hydrocarbons in the exhaust gases, during phases of rise in catalyst temperature <B> 28. </ B>

Advantageously, a catalyst <B> 28 </ B> is disposed in exhaust duct, not shown, located downstream and <B> at </ B> immediate proximity of each exhaust valve. The distance separating the catalysts <B> 28 </ B> from the combustion chamber being minimum, the temperature of the exhaust <B> G </ B> is maximum. This optimizes the effectiveness of the catalyst. <B> 28. </ B> Thus, the powertrain <B> 10 </ B> according to the invention makes it possible to significantly reduce the quantity of pollutants and especially oxides. nitrogen, carbon monoxide and unburnt hydrocarbons present in the exhaust gases <B> G </ B> emitted by engine 12 <B> to </ B> internal combustion supercharged by a turbocharger <B> 18, </ B> such as a diesel engine and a <B> to </ B> gasoline <B> to poor mix engine.

Claims (1)

<B> <U> CLAIMS </ U> <B> 1. </ B> <B> (10) </ B> </ B> </ B> </ B> </ B> </ B> / B> internal combustion supercharges a turbocharger <B> (18), </ B> an intake circuit (14) or fuel-air mixture and an exhaust system <B> (16) </ B> burns that comprise an exhaust pipe (42) connects the exhaust of at least one combustion chamber of a cylinder, <B> to </ B> a turbine (24) of the turbocharger <B> (18) </ B> with interposition of a catalyst <B> (28), </ B> characterized in that recirculation line (48) connects a point (49) of the exhaust line to the intake circuit, so that <B > to </ B> allow recirculation of exhaust gases in the combustion chamber of at least one cylinder. 2. Power train <B> (10) </ B> according to the preceding claim, characterized in that the point (49) of the exhaust pipe (42) is located downstream of the catalyst <B> (28) < / B> and upstream of the turbine (24). <B> 3. </ B> Power train <B> (10) </ B> according to the preceding claim, characterized in that the recirculation pipe (48) comprises regulating means <B> (50) </ B> exhaust gas flow. 4. Power train according to any one of the preceding claims, characterized in that the recirculation line (48) comprises cooling means <B> (52) </ B> of the exhaust gas. <B> 5. </ B> <B> (10) </ B> </ B> According to the preceding claim, characterized in that the cooling means <B> (52) </ B> of the exhaust gases comprise a heat exchanger. <B> 6. </ B> Power train <B> (10) </ B> according to any one of the preceding claims, characterized in that the engine (12) comprises several combustion chambers, in that each chamber of combustion is connected <B> to </ B> at least one associated conduit (43) of an exhaust manifold (44) in which is interposed a catalyst <B> (28), </ B> and the associated ducts (43) meet in at least one exhaust duct (42) upstream of the turbine (24). <B> 7. </ B> Power train <B> (10) </ B> according to any one of the preceding claims, characterized in that each a combustion chamber comprises at least one exhaust valve, in that each exhaust valve is connected to an associated exhaust duct in which a catalyst is interposed, and in that the associated exhaust ducts meet in an exhaust duct (42) unique upstream of the turbine (24). <B> 8. </ B> Power train according to any one of the preceding claims, characterized in that an air cooling device <B> (26) </ B> is interposed in the intake circuit (14) between the downstream of the compressor (22) of the turbocharger <B> (18) </ B> and the upstream of the engine (12).