EP1952008A1

EP1952008A1 - Internal combustion engine with stratification of intake gases

Info

Publication number: EP1952008A1
Application number: EP06820320A
Authority: EP
Inventors: Fabien Sauton; Cédric Servant; Jean-Marc Duclos
Original assignee: Renault SAS
Current assignee: Renault SAS
Priority date: 2005-11-21
Filing date: 2006-10-19
Publication date: 2008-08-06
Also published as: CN101313140B; FR2893672B1; WO2007057587A1; FR2893672A1; RU2008125122A; RU2392471C2; CN101313140A

Abstract

The invention relates to an internal combustion engine for a motor vehicle comprising a number of cylinders (1) each provided with at least one intake port (3, 7) for air and recycled exhaust gases (EGR) and with at least one exhaust port (9, 10), a bypass port (15) with a valve (16) for controlling the flow rate of recycled exhaust gases (EGR) linking the exhaust port to the intake port at a junction point (21, 22), characterized by the fact that the air intake port (3a, 7a) comprises a valve (17a, 18a) for controlling the air flow rate that is placed inside the air intake port upstream from the junction point (21, 22), and that controlling means (23) are capable of acting upon the valve for controlling the flow rate of the recycled exhaust gases (EGR) and upon the valve for controlling the air flow rate whereby alternatively drawing, via the intake port, either the air or the recycled exhaust gases (EGR).

Description

Internal combustion engine with stratification of the intake gases.

The present invention relates to combustion in internal combustion engines, and more particularly to compression ignition engines of the diesel type, for automotive vehicles.

In internal combustion engines of this type, a mixture of air and exhaust gas recycled and therefore depleted of oxygen is generally used for admission to the combustion chamber. Such a mixture makes it possible to reduce polluting emissions or, as the case may be, to control the progress of combustion. These recycled exhaust gases are called "external exhaust gas recirculation" or EGR ("Exhaust Gas Recirculation") when they come from the combustion chamber and are reintroduced at the intake by a circuit external to the chamber of combustion. These gases are called "internal" or BGR (for "Burned Gas Recirculation") when it comes to residual combustion gases that remain trapped in the combustion chamber. The present invention essentially relates to the management of the external recycled exhaust gases (EGR) and to the manner of introducing these gases into the combustion chamber in order to obtain the desired effects, and in particular a stratification of the gases admixed. s in the combustion chamber. Patent Application GB-A-2 328 716 (FORD) seeks to obtain a stratification of the EGR gases in the combustion chamber around the axis of the cylinder by introducing these gases by means of a specific duct which brings the EGR gas at the point of the control valve. The fresh air intake duct has a pivoting flap that regulates the flow of fresh gases in the intake duct. The objective sought in this prior document is essentially to maintain the recycled exhaust gas in the center of the combustion chamber. US-A-5918577 discloses a radial stratification system of burnt gases in the combustion chamber of an internal combustion engine by re-suction through the exhaust valves of gases previously removed during the exhaust phase . The exhaust gases in question are therefore residual gases, that is to say recycled exhaust gases.

"Internal". The stratification of these burned gases around the axis of the cylinder is obtained by a control of the exhaust gas flow rates in certain zones of the combustion chamber.

US-A-6318348 (VISTEON) also mentions a radial stratification of the gases admitted into the combustion chamber, the whole of the charge being rotated along the axis of the cylinder and the residual flue gases being maintained preferentially on the circumference of the cylinder. Again, it is a stratification of recycled exhaust gases called "internal", which are maintained preferentially on the circumference of the cylinder.

British Patent Application GB-A-2 298 896 (FORD) uses two intake ducts, one of which is divided into two parts by a partition, so as to be able to introduce through the corresponding intake valve, an air mixture and EGR gas. Radial or vertical stratification is obtained by controlling the flow of the admitted EGR gas.

A somewhat similar arrangement is described in the French patent application FR-A-2860555 (RENAULT), in which an intake duct is separated in two parts by a movable wall, to modify the passage section for the EGR gases and for the mixture of air and fuel admitted.

The French patent application FR-A-2 859765 (RENAULT) describes the use of two intake ducts receiving a mixture of air and EGR gas, each of the ducts being able to be supplied with additional air or additional EGR gas. .

British Patent Application GB-A-2328980 (IFP) discloses a branching of an EGR gas bypass duct in the air intake duct in a cylinder and furthermore describes the addition of a device allowing orient the admitted gases by sticking them against the walls of the combustion chamber in order to obtain a radial stratification.

In all these known devices, when an introduction of EGR gas is provided, this is done by mixing the EGR gas homogeneously with the intake air through a stitching taken on the exhaust pipe which reinjects the EGR gas on admission.

It should further be noted that the residual gases, i.e. the internal exhaust gases, are hotter than the external recycled exhaust gases, so that the problems which arise for the stratification of these gases are different, depending on whether it is residual gas or external gas.

Contrary to what is indicated in certain documents of the prior art, the object of the present invention is to stratify the external recycled exhaust gases (EGR) around the axis of the cylinder in the combustion chamber of a cylinder. particularly simple and effective way.

In one embodiment, the internal combustion engine for a motor vehicle is of the type comprising several cylinders each provided with at least one intake duct for air and gas. exhaust system (EGR) and at least one exhaust pipe, a bypass pipe with a recirculated exhaust gas flow control valve (EGR) connecting the exhaust duct to the intake duct a junction point. The air intake duct comprises an air flow control valve, mounted in the air intake duct upstream of the junction point. Control means are able to act on the recycled exhaust gas flow control valve (EGR) and on the air flow control valve so as to admit alternately through the intake duct, or the air is recycled exhaust gas (EGR). These control means may for example comprise an electronic control unit installed in the motor vehicle and suitably programmed or include electronic circuits capable of delivering control signals for the control valves.

The alternative intake of recycled air and exhaust gas (EGR) enables the combustion chamber in the cylinder to be fed sequentially and thus to obtain a stratification of the recycled exhaust gases in the combustion chamber. around the axis of the cylinder. Indeed, the speed of the admitted gases depends on various factors related to the operation of the engine and in particular the speed and the position of the piston which moves in the cylinder. The different gases being admitted sequentially into the combustion chamber, will have a different speed resulting in stratification of these gases in the combustion chamber.

Preferably, means are provided for regulating the speed of the gases admitted into the cylinder.

These means may comprise, for example, an adjustable flap mounted in the air intake duct downstream of the point of junction. The position control of such a flap can be provided by signals generated by the electronic control unit.

In another embodiment, the means for controlling the velocity of the gases admitted to the cylinder may comprise means for controlling the opening movements of intake valves. These control means may for example comprise sensors for speed and / or position of the piston. The signals from these sensors can be transmitted to an electronic control unit generating control signals for the intake valves.

In other embodiments, the means for regulating the speed of the gases admitted into the cylinder may comprise different mobile members also used to control the aerodynamics of the gases in the combustion chamber, for example a swirl flap, it is to say a shutter capable of creating a rotational movement of the gases in the combustion chamber around the axis of the cylinder, this movement being called "swirl".

The invention can also be applied to the case of engines comprising several intake ducts for each cylinder. In this case, each intake duct comprises an air flow control valve, mounted in the air intake duct upstream of the junction point.

Another aspect of the invention relates to a method for controlling the intake of recycled air and exhaust gas (EGR) in a cylinder of an internal combustion engine of a motor vehicle, in which it is admitted in the cylinder, alternatively either air or recycled exhaust gas (EGR). According to one embodiment, the alternative admission sequences are piloted as a function of the position or the speed of the piston in the cylinder.

The speed of the gases admitted to the cylinder can also be controlled.

The invention will be better understood from the study of a particular embodiment described by way of non-limiting example and illustrated by the appended drawing, which schematically shows in top view an internal combustion engine cylinder and the various ducts. intake and exhaust.

As illustrated in FIG. 1, the upper part of a cylinder 1 of an internal combustion engine and in particular of a diesel-type compression ignition engine is shown schematically. Of course, the engine comprises several identical cylinders. Different intake and exhaust ports are provided at the junction between the cylinder head, not shown, and the cylinder 1. A first intake duct 3 opens into a first inlet 4 and allows the sequential admission, either a stream of fresh air shown schematically by the arrow 5, conveyed in a bypass 3a, or an external recycled exhaust stream

EGR schematized by the arrow 6, conveyed in a branch 3b.

A second inlet duct 7 opens into a second inlet orifice 8 and also allows the admission of either a stream of fresh air, shown schematically by an arrow 5, conveyed in a bypass 7a, or, sequentially, a stream of recycled exhaust gas EGR symbolized by an arrow 6 and conveyed in a branch 7b.

The cylinder also comprises two exhaust ducts 9 and 10 which each open into an exhaust port 11, 12, and allow the escape of the combustion gases in a flow materialized by the arrow 6 by an exhaust duct 13 in which the two ducts 9 and 10 meet. Substantially in the axis of the cylinder, there is mounted a fuel injector 14 able to inject a cloud of fuel at a suitable time in the combustion chamber.

The four orifices 4, 8, 11 and 12 are, in the illustrated example, arranged substantially at regular intervals around the periphery of the cylinder 1. The orifices are of circular section and may be alternately open and closed by means of valves, represented. The intake ports 4 and 8 are arranged on the same side of the cylinder 1, while the exhaust ports 11 and 12 are arranged on the other side.

An external bypass circuit, materialized by the duct 15, stitched on the exhaust duct 13, allows the recirculation of a part of the exhaust gas, shown schematically by an arrow 6, in the direction of admission. A controlled valve 16, called "EGR valve", regulates the flow of recycled exhaust gas EGR according to the operation of the combustion engine. In each of the bypass ducts 3a, 3b and 7a, 7b, there is arranged a controlled control valve. Thus, in the bypass duct 3a, a valve 17a is mounted and in the bypass duct 3b, a valve 17b. In the same manner, in the bypass duct 7a, a valve 18a is mounted and in the bypass duct 7b, a valve 18b. The control of these different control valves makes it possible to open or close the bypass ducts concerned. In this way, it is possible to admit into the intake port 4 via the intake duct 3, alternatively, either fresh air symbolized by the arrow 5 by the bypass duct. 3a when the control valve 17a is open, or a stream of recycled exhaust gas symbolized by the arrow 6 by the bypass duct 3b when the control valve 17b is open. When the control valve 17a is open, the control valve 17b is closed and vice versa. In this way, the gases admitted through the intake duct 3 are sequentially fresh air, then EGR recycled exhaust gas or vice versa.

We find the same operation for the intake duct 7, which can alternatively convey a fresh air flow symbolized by the arrow 5, by the bypass duct 7a when the control valve 18a is open and, sequentially, a EGR gas flow through the bypass duct 7b when the control valve 18b is open. In the same way as for the control valves 17a and 17b, the control valves 18a and 18b are alternately, either open or closed, and when one of them is open, the other is closed, so the intake duct 7 sequentially conveys either a fresh air flow or an EGR gas flow.

The speed of the gases admitted by the intake ducts 3 and 7 is dependent on the speed of the piston which moves inside the cylinder 1. The different types of gas being admitted into the combustion chamber sequentially, each The sequence will therefore have a different speed during admission to the combustion chamber. These differences in speed between each type of gas and result, according to the invention, a stratification of the gases in the combustion chamber.

Thanks to the invention, it therefore becomes possible to take advantage of the evolution of the aerodynamics of the gases inside the chamber of combustion during the process of admission into the cylinder to obtain the desired stratification of the different gases admitted.

In the example illustrated in the figure and as an optional variant, there is further provided in the two intake ducts 3 and 7 an adjustable flap 19, 20, so as to change the speed of the gases admitted by the ducts. admission 3 and 7.

It will be noted that the control valves 17a, 17b and 18a, 18b are arranged in the respective bypass ducts 3a, 3b and 7a, 7b, upstream of the junction point 21 or 22, where the respective bypass ducts 3a, 3b and 7a, 7b join to form the single inlet duct 3 or 7. In this way, it is understood that a closing action of one of the control valves makes it possible to completely block the flow of the gas considered in the duct in which the regulating valve considered is mounted. In this way, the flow of gas admitted during the sequence corresponding to the closing of one of the control valves and the opening of the other control valve is indeed a gas consisting solely of either fresh air or recycled exhaust gas (EGR). On the contrary, the adjustable flaps 19, 20, when they are provided, are mounted in the intake ducts 3, 7 downstream of the junction points 21, 22 so as to act on the speed of the admitted gas flow, which whatever its nature.

The control of the different control valves 17a, 17b and 18a, 18b, as of the EGR valve 16, and the shutters 19, 20 when present, is carried out by means of an electronic control unit 23, denoted ECU on the figure. This electronic control unit receives, by the connections symbolized by the arrow 24, different parameters of the operation of the engine and can generate various control signals that are transmitted through the connection to the EGR valve 16, through the connections 26 and 27 to the movable flaps 19 and 20, through the connections 28 and 29 to the control valves 17a and 17b, and through the connections 30. and 31 to the control valves 18a and 18b. The gas sequences in the combustion chamber are then generated as a function of the control strategies of the control valves 17a, 17b and 18a, 18b defined for example by a control software stored in the electronic control unit. 23. In the same way, the speed of the admitted gases can be punctured by the position of the flaps 19 and 20.

By introducing such different gas sequences into the combustion chamber at different speeds, these gases tend to be on a different radius around the cylinder axis, thus providing stratification in the combustion chamber.

It is also possible to take into account signals emanating from sensors of the position or speed of movement of the piston in the cylinder 1, these sensors not being shown in the figure. The signals emitted by such sensors can be taken into account by the electronic control unit 23 to act on the control strategies of the different control valves.

In another mode of regulation, not described in the figure, it is also possible to envisage using a variable distribution device by appropriately controlling, by signals transmitted by the electronic control unit, the opening movements. and closing the intake and exhaust valves.

Although in the illustrated example, the cylinder 1 has had two intake ducts, it will of course be understood that the invention applies to other structures, for example comprising a single intake duct.

Claims

1-Internal combustion engine for a motor vehicle, of the type comprising several cylinders (1) each provided with at least one intake duct (3, 7) of recycled air and exhaust gas (EGR) and of at least one exhaust duct (9, 10), a bypass duct (15) with a recirculated exhaust gas flow control valve (EGR) connecting the exhaust duct to the intake duct at a junction point (21, 22), characterized in that the air intake duct (3a, 7a) comprises an air flow control valve (17a, 18a), mounted in the air duct air intake upstream of the junction point (21, 22) and that control means (23) are able to act on the recycled exhaust gas flow control valve (EGR) and on the valve regulating air flow so as to admit alternately through the intake duct, either air or recycled exhaust gas (EGR).

2-engine according to claim 1, further comprising means for regulating the speed of the gases admitted into the cylinder.

3-motor according to claim 2, wherein the means for regulating the speed of the gases admitted into the cylinder comprise an orientable flap (19, 20) mounted in the air intake duct downstream of the junction point.

4-motor according to claim 2, wherein the means for regulating the speed of the gases admitted into the cylinder comprise means for controlling the opening movements of the intake valves.

5-engine according to one of the preceding claims, comprising a plurality of intake ducts for each cylinder, wherein each intake duct comprises a control valve of air flow, mounted in the air intake duct upstream of the junction point.

6-Process for controlling the intake of recycled air and exhaust gas (EGR) in a cylinder of an internal combustion engine of a motor vehicle, characterized in that the cylinder is admitted alternately the air is recycled exhaust gas (EGR).

7-Process according to claim 6, wherein one pilot the alternative admission sequences as a function of the position or the speed of the piston in the cylinder.

8-Process according to claims 6 or 7, wherein it also controls the speed of the gases admitted into the cylinder.