FR2931897A1 - METHOD FOR DECREASING AN EXHAUST GAS RECIRCULATION VALVE AND INTERNAL COMBUSTION ENGINE - Google Patents

Abstract

A method for slurrying a valve (11) mounted in a recirculation circuit (5) of the exhaust gases of an internal combustion engine taken upstream of a turbocharger (2), the valve being equipped with a means operable obstruction (12). The scrubbing is done by injecting a liquid into the recirculation circuit (5). The injected liquid is an aqueous liquid. The injection is made in the valve (11) in the vicinity of the obstruction means (12) of the valve (11).

Description

B08-0837EN - EGA / EVH

Simplified joint-stock company known as: RENAULT s.a.s. A method of slagging an exhaust gas recirculation valve and an internal combustion engine. Invention of: CHENUET Laurent

A method of scrubbing an exhaust gas recirculation valve and an internal combustion engine. The invention relates to the field of internal combustion engines of the gasoline or diesel type, producing exhaust gases which contain polluting substances such as nitrogen oxides (NOx). In particular, the invention relates to devices and methods for recirculating the exhaust gases that are taken downstream of the engine and reintroduced into the engine intake circuit through a valve called EGR valve. The exhaust gases are loaded with particles and soot that can settle in the EGR valve and gradually alter its operation.

The invention relates to the field of EGR valve slagging processes as well as engines using the method. During the recirculation of the exhaust gas, the nitrogen and oxygen of the intake air are mixed with the exhaust gases and in particular with the carbon dioxide (CO2) from the exhaust gas. CO2 has a higher heat capacity than other gases in the air. During the release of energy caused by the combustion of the fuel, the rise in temperature in the combustion chamber is reduced compared to the same energy release in a volume of air without CO2. This reduction in temperature decreases the proportion of NOx emitted. There are several types of recirculation processes depending on where the exhaust gases are taken. The recirculated gases can be taken upstream of the turbine of the turbocharger, it is called high pressure EGR. The recirculation gases can be taken downstream of the turbine, the oxidation catalyst and the particulate filter, referred to as low pressure EGR. The high-pressure EGR processes have the advantage of reducing the unburned hydrocarbon content as well as the carbon monoxide (CO) level emitted. This type of recirculation is suitable for vehicle start-up or for urban traffic, when the engine is still cold. Recirculating gases in high pressure EGR devices are more loaded with particulates and soot than in low pressure EGR devices. EGR valve scrubbing is especially necessary for high pressure EGR devices. Patent application WO 00/47344 proposes an apparatus for cleaning the exhaust gas recirculation system. A solvent is injected. This method has the disadvantage of using a product harmful to health and the environment. Patent application JP 55 072 644 describes a device for preventing the blocking of an EGR valve. A nozzle makes it possible to introduce air upstream of the EGR valve. Such a method has the disadvantage of increasing the proportion of oxygen in the recirculation gases and therefore in the combustion chamber. During the EGR valve scrubbing stages, the advantage of exhaust gas recirculation is reduced and the pollution emitted increases. The patent application FR 2 869 648 describes a sludge removal device of the exhaust gas recirculation circuit. A scrubbing liquid is injected into said circuit, and in particular a flammable liquid such as gasoline. The described scrubbing is caused by the inflammation of the injected gasoline that burns the oil and soot particles deposited in the circuit. Such a scrubbing method has the disadvantage of raising the temperature of the gases entering the combustion chamber of the engine. This temporarily increases the pollution emitted by the combustion. It can also risk degrading some engine components such as valves. This can also cause combustions at an inappropriate moment in the combustion cycle, and cause an effect called rattling. The invention proposes a method of slagging the EGR valve and a motor using this method, overcoming the above disadvantages, and in particular making it possible to improve the cleaning of the particles deposited in the EGR valve, without raising the temperature of the recirculated gases, without disrupt the combustion cycle of the engine. According to one embodiment, the invention relates to a method of slagging a valve mounted in an exhaust gas recirculation circuit of an internal combustion engine taken upstream of a turbocharger, the valve being equipped with an operable obstruction means. The scrubbing is done by injecting a liquid into the recirculation circuit. The injected liquid is an aqueous liquid. The injection is made in the valve in the vicinity of the obstruction means of the valve. The aqueous liquid has a vaporization temperature lower than that of the exhaust gas. Because of the very high heat capacity of the water, the vaporization of the aqueous liquid causes a greater and more sudden cooling of the exhaust gases present in the EGR valve than during the injection of any liquid. This sudden cooling affects, by thermal conduction of gases, a cooling zone wider than where the aqueous liquid is sprayed. The thermal shock causes the separation of particles and soot throughout the cooling zone. Thus, thanks to the very high heat capacity of the aqueous liquid injected, the soot is peeled even in places not reached by the jet of sprayed aqueous liquid. The thermal shock of recirculated exhaust gas cooling is more efficient than the simple kinetic energy of the injected liquid jet. In addition, the aqueous liquid does not ignite and does not raise the temperature of the recirculating gases. Finally, the water vapor passes through the combustion chamber of the engine without being chemically altered. The water molecule is not dissociated. Such a process has no harmful effect on the environment.

Advantageously, the injection is done by a succession of individual injections lasting less than one second. According to one variant, the individual injections are distributed temporally in a regular manner.

According to one variant, the sludge phases of the valve are determined as a function of parameters of the rotational speed of the engine and / or of the requested acceleration setpoint, and / or of the open state of the valve.

In another aspect, the invention relates to an internal combustion engine equipped with a turbocharger and an exhaust gas recirculation circuit taken upstream of the turbocharger. The recirculation circuit is provided with a valve. The valve comprises an injection means located inside the valve.

The injection means is adapted to inject water. According to one embodiment, the valve comprises obstruction means, the injection means being located upstream of the obstruction means. According to another embodiment, the valve comprises obstruction means having an obstruction section, the injection means being located at a distance from the obstruction means less than twice the equivalent diameter of the obstruction section . According to another embodiment, the injection means is located at a distance from the obstruction means such as a quantity of water sprayed at ambient temperature in exhaust gases at a temperature greater than 200 ° C. passing through said valve, is suitable for said distance to cool the gas with a gradient greater than 50 ° C / s and preferably greater than 100 ° C / s.

According to a variant, the injection means is a capillary, opening into the valve, equipped with a check valve and connected to a water tank via a feed pump. According to another variant, the injection means is a controllable injector.

Other features and advantages of the invention will appear on reading the detailed description of an embodiment taken by way of non-limiting example and illustrated by the appended drawing, in which FIG. 1 is a diagram illustrating an engine. internal combustion.

As illustrated in FIG. 1, the internal combustion engine 1 is equipped with a turbocharger 2, an intake circuit 3, an exhaust system 4 and an exhaust gas recirculation circuit. 5. The intake circuit 3 brings fresh air through a compression stage 6 of the turbocharger 2 and feeds a plurality of combustion chambers 7. The exhaust circuit 4 collects the exhaust gases from the combustion chambers 7 and feeds a turbine stage 8 of the turbocharger 2.

A bypass 9 for sampling a portion of the exhaust gas is located in the exhaust circuit 4 between the combustion chambers 7 and the turbine stage 8. The exhaust gas recirculation circuit 5 connects the bypass 9 to a junction point 10 of the intake circuit 3. The recirculation circuit 5 comprises a valve 11 commonly referred to as the EGR valve. The recirculation circuit 5 is a high pressure type circuit because the bypass point 9 is upstream of the turbine 8 and the junction point 10 is downstream of the compressor 6. The pressure of the exhaust gases in the bypass 9 from the heated gases thus expanded by the combustion in the combustion chambers 7. The pressure in the bypass 9 is greater than the pressure in the junction point 10, so that the exhaust gas recirculation flow rate is mainly controlled by the EGR valve 11. The recirculation circuit 5 may also include a recirculating gas cooler. The EGR valve 11 comprises an obstruction means 12 for interrupting the flow of exhaust gas flowing from the bypass 9 to the junction point 10. According to one variant, the obstruction means 12 are of the shutter type. butterflies. A disc 13 pivots about an axis 14. In a closed position, the disc 13 obscures an obstruction section 15. In this variant, the valve 11 has an upstream duct 16 and a downstream duct 17 substantially aligned. The axis 14 is substantially perpendicular to the axis of the upstream and downstream ducts 16, 17. In the closed position, the disc 13 is substantially perpendicular to the axis of the ducts 16, 17. In a maximum open position, the disc 13 is substantially parallel to the axis of the ducts 16, 17.

In another variant, the obstruction means 12 are of the valve type. In this variant, the valve has a perpendicular axis with an obstruction section delimited by a seat. In either variant, the pressure of the exhaust gases undergoes significant variations when passing through the obstruction section 15. This has the effect that the soot contained in the exhaust gas passing through through the recirculation circuit 5 are preferably deposited in the vicinity of the obstruction section, the butterfly flap, or the seat and the valve. In general, the soot is deposited primarily in the vicinity of the obstruction means 12. This has the effect of hindering the operation of the obstruction means 12, and in particular, to degrade the seal. This also has the effect of modifying the obstruction section 15 and therefore the flow rate of gas likely to pass through the EGR valve for a given position of said obstruction means 12. An injector 18 is disposed inside the EGR valve 11 and is connected to a water reservoir 19 via a feed pump 20. The injector 18 sprays liquid water in the form of droplets inside exhaust gas whose temperature is higher than 200 ° C. . This immediately causes a vaporization of the water by consuming the calories necessary for the vaporization and proportional to the latent heat of the water. This consumption of calories is brutal and causes a sudden cooling of the gas around the spray. This cooling propagates beyond the space receiving the water droplets. The thermal shock propagates and can thus reach areas of the obstruction means in which the soot is deposited while these areas are not reachable by the jet of liquid.

The thermal gradient caused by the sudden vaporization of water at room temperature in gases greater than 200 ° C decreases as one moves away from the injection point. The distance between the injection point and the obstruction section is less than twice the equivalent diameter of said obstruction section 15. It is also possible to define this distance by the minimum cooling gradient that causes the water spraying to occur. ambient temperature in exhaust gases above 200 ° C. This minimum gradient can be 50 ° C / second and preferably greater than 100 ° C / second. The thermal shock causes the detachment of soot deposited by the flow of exhaust gas in the EGR valve 11. The injector 18 can be disposed upstream of the obstruction means 12. The thermal shock phenomenon and its propagation occur that the obstruction means 12 are open or closed. The injector 18 may also be placed inside the EGR valve on the downstream side of the obstruction means 12 at a distance such that the thermal shock can propagate to the obstruction means 12.

A control unit 21 can be connected to a sensor sensitive to the position of the crankshaft of the engine. The control unit 21 can also be connected to a means for determining an exhaust gas recirculation flow setpoint directly controlling the EGR valve 11.

The control unit 21 can determine the desired scrubbing phases of the EGR valve 11. During these slagging phases, the control unit 21 controls the injector 18 or the pump 20 so as to generate a succession of individual injections. expected duration, for example less than 1 second.

Thus, during the scrubbing phases, a succession of thermal shocks reach the obstruction means 12 and take off the soot deposited thereon. Optionally, the intake circuit 3 comprises an air filter 22. The exhaust circuit 4 may comprise, downstream of the turbine 8, an oxidation catalyst 23 and / or a particulate filter 24.

Claims (10)

REVENDICATIONS1. A method of removing a valve (11) mounted in a recirculation circuit (5) of the exhaust gases of an internal combustion engine taken upstream of a turbocharger (2), the valve (11) being equipped with an obstructing means (12) operable, the slag being produced by injecting a liquid into the recirculation circuit (5), characterized in that the injected liquid is an aqueous liquid and the injection is made in a the valve (11) in the vicinity of the obstruction means (12) of the valve (11). 2. The method of claim 1, wherein the injection is by a succession of individual injections lasting less than one second. 3. Method according to claim 2, wherein the individual injections are distributed temporally in a regular manner. 4. Method according to one of the preceding claims, wherein one determines the stages of slagging of the valve as a function of parameters of the rotational speed of the motor and / or the requested acceleration setpoint, and / or the state opening of the valve (11). 5. Internal combustion engine equipped with a turbocharger (2) and a recirculation circuit (5) for the exhaust gases taken upstream of the turbocharger (2), the recirculation circuit (5) being provided with a valve (11), characterized in that the valve (11) comprises an injection means (18) located inside the valve (11), the injection means being adapted to inject water. 6. Engine according to claim 5, wherein the valve (11) comprises obstruction means (12), the injection means (18) being located upstream of the obstruction means (12). 7. Motor according to claim 5 or 6, wherein the valve (11) comprises obstruction means (12) having an obstruction section (15), the injection means (18) being located at a distance from the obstruction means (12) less than twice the equivalent diameter of the obstruction section (15). 8. Motor according to one of claims 5 to 7, wherein the injection means (18) is located at a distance from the obstruction means (12) such as a quantity of water sprayed at room temperature in exhaust gas at a temperature above 200 ° C passing through said valve (11), is suitable for said distance to cool the gas with a gradient greater than 50 ° C / s and preferably greater than 100 ° C / s. 9. Motor according to one of claims 5 to 8, wherein the injection means (18) is a capillary, opening into the valve (11), equipped with a non-return valve and connected to a water reservoir ( 19) via a feed pump (20). 10. Motor according to one of claims 5 to 9, wherein the injection means is a controllable injector.