FR2663686A1 - Petrol engine including an improved indirect injection device and corresponding injection method - Google Patents

Abstract

The petrol injector (14) which is of a conventional type in the case of indirect injection devices and which is fed with petrol at low pressure emerges into the intake port (7). The injector (14) is placed and directed so that it injects a jet of petrol (15) at a given instant in the operating cycle of the engine, towards the combustion chamber (5) and inside this chamber (5) in the case where injection takes place at the moment when the intake valve (10) opens. Injection may be carried out directly into the combustion chamber (5) in contact with the internal surface (12a) of an exhaust valve (12), the intake valve (10) being open or in contact with the external surface (10b) of the intake valve (10) in the closed position at the moment of injection.

Description

 The invention relates to a petrol engine comprising an improved indirect injection device.

Petrol injection engines generally have, associated with each of their cylinders, an injection device which may be of the direct or indirect type.
The direct injection devices include an injector, the end or nose of which exits the gas jet injected under a certain pressure opens into the combustion chamber formed inside the cylinders.

The indirect injection devices include an injector disposed in the cylinder intake duct, the end of which opens into the combustion chamber, through an orifice which can be closed by the corresponding intake valve. The injector is placed and directed inside the intake duct, so that most of the injected gasoline hits the internal walls of the intake duct or the exterior surface of the intake valve directed towards the intake duct and opposite the combustion chamber, before entering the interior of the combustion chamber,
The direct injection devices have the disadvantage of requiring the injection of the fuel jet, at a high pressure of the order of several tens of bars. It is therefore necessary to use injectors which can operate at fairly high pressures as well as a petrol supply circuit capable of supplying the injector with petrol at the desired pressure. In particular, the pipes, the fuel pump and the fuel system pressure regulator must be designed to withstand the high pressures necessary for injection.
In addition, the nozzle of the injector which is placed inside the combustion chamber must be able to withstand the high temperatures and pressures which prevail inside this chamber, during the operation of the engine.

 Direct injection devices are therefore much more complex and much more expensive than indirect injection devices which can operate at a low pressure, of the order of 3 bars and whose injector opens into the intake duct c that is to say in an area which is not subjected to high pressures and temperatures.

However, in the case of indirect injection devices, most of the petrol injected is deposited in the form of a liquid film on the walls of the intake pipe u on the exterior surface of the intake valve, before d be sucked inside the combustion chamber, with a delay compared to 1 injection
The quantity of petrol which is deposited in the form of a liquid film on the walls of the intake duct depends on the temperature of these walls and on the pressure which prevails in the intake circuit of the engine. Consequently, the quantity of petrol entering the combustion chamber does not correspond to the quantity delivered by the injectors which are controlled by the electronic engine control computer. Significant deviations can be observed in particular during the operating phases. in transient conditions, during which the pressure in the intake duct varies very rapidly.

 It is therefore not possible to take full advantage of the performance of the electronic engine control computer to adjust the quantity of fuel sent to the combustion chamber very precisely and instantly. Such a fine-tuned and instantaneous adjustment is necessary to reduce the emission of polluting gases and to improve the operating stability of the engine, in particular in transient conditions.

On the other hand, in the case of a cold start of the engine, the rise in temperature of the internal walls of the intake circuit of the engine may be relatively slow, so that the conditions favorable to good injection and vaporization satisfactory gasoline cannot be reached quickly
Up to now, no indirect type injection device has been known which requires only low injection pressures and which makes it possible to avoid the drawbacks of known devices, in particular the difficulties of adjusting the quantity of gasoline introduced into the combustion chamber in transient regime and the formation of polluting gases.

The object of the invention is therefore to propose an injection petrol engine comprising at least one cylinder in which a combustion chamber is formed, at least one intake duct of which one end communicates with the combustion chamber through an orifice, at least one intake valve for closing or opening the orifice of the intake duct and a petrol injector opening into the intake duct, this engine making it possible to perform an injection in a perfectly regulated manner whatever its speed and limit the formation of polluting gases in the combustion chamber, despite indirect indirect low-pressure injection
For this purpose, the injector is placed and directed so as to inject a jet of petrol, at a determined instant in the engine operating cycle, towards the combustion chamber and inside this chamber, in the event that the injection takes place at the time of opening of the intake valve.

 In order to make the invention understood, we will now describe, by way of nonlimiting example, with reference to the attached figures, an injection engine according to the invention and various modes of operation and adjustment of this engine. .

 Figure 1 is a vertical sectional view along 1-1 of Figure 2, of the upper part of the cylinder of an injection engine according to the invention.

 Figure 2 is a top view along 2-2 of Figure 1.

 As shown in FIG. 1, the engine comprises a cylinder block 2 and a cylinder head 3 attached to the cylinder block, along a joint plane 4.

 The cylinder block 2 and the cylinder head 3 are machined so as to constitute several cylinders such as the cylinder 1, the upper part of which is shown in FIG. 1.

 The cylinder 1 comprises a combustion chamber 5 machined in the cylinder block 2 and closed at its upper part by the cylinder head 3. A piston 6 is movably mounted inside the combustion chamber 5 into which the part opens out. upper, an intake duct 7 and an exhaust duct 8 machined inside the cylinder head 3. The end portion of the intake duct 7 opening into the combustion chamber 5 has an orifice along which is disposed a valve seat 9 comprising a sealing surface intended to cooperate with a corresponding sealing surface of the valve 10, in the closed position of this valve.

Similarly, the exhaust duct 8 comprises, at its end opening into the combustion chamber 5, an orifice along which is arranged a valve seat 11 comprising a sealing surface intended to cooperate with a corresponding sealing surface d an exhaust valve 12, in the valve closed position
The inlet valve 10 and the exhaust valve 12 have valve stems mounted movably in the cylinder head 3, so as to ensure the opening or closing of the corresponding valve.

 The displacements of the valves 10 and 12 are ensured by means of cam shafts and return springs, not shown.

 In FIG. 1, the inlet valve 10 has been shown in its open position and the exhaust valve 12 in its closed position.

 The valves 10 and 1 are placed in a V-shaped arrangement and the valve seats 9 and 11 are placed in positions offset in a transverse direction from the chamber 5 of the cylinder 1, as seen in FIG. 2.

 As will be explained below, the invention can be applied equally to an engine with two valves per cylinder or to an engine with four valves per cylinder arranged in a V.

 According to the invention, an injector 14 of a type commonly used in the case of indirect injection devices is placed in a housing machined in the cylinder head 3 and opens out in the vicinity of the end portion of the intake duct. 7.

 The nose 14a of the injector through which a jet 15 of gasoline under pressure exits at a determined instant of the engine operating cycle is slightly set back relative to the duct 7 inside the housing machined in the cylinder head.

 The injector 14 is directed so that the jet 15 of small cross section passes through the end orifice of the intake duct 7 and the valve seat 9, when the injection of the fuel jet is carried out while the valve intake 10 is in its open position as shown in Figure 1.

 As can be seen in FIGS. 1 and 2, the jet 15 of very small section can penetrate into the combustion chamber 5, when the intake valve 10 is open, to strike the interior surface 12a of the exhaust valve 12 in its closed position, that is to say the flat surface of this valve directed towards the combustion chamber.

 The position and direction of the jet 15 are precisely adjusted, so that the jet 15 cannot come into contact with any part of the valve 10 in its open position.

 The injector 14 is supplied by a conventional type fuel circuit in the case of indirect injection devices, so as to deliver a jet of gasoline at a pressure of the order of 3 bars, at a determined time of engine operating cycle.

 In a first operating mode of the engine, the injection of the fuel jet 15 is carried out when the intake valve 10 is in its open position. The fuel jet 15 then enters the combustion chamber and comes into contact with the interior surface 12a of the exhaust valve 12 in the closed position, this surface 12a constituting a hot zone of the interior wall of the combustion chamber. 5.

 This operating mode has the advantage of allowing direct injection into the combustion chamber 5 of the cylinder 1 without the jet of petrol coming into contact with the internal wall of the intake duct 7 or with the external surface 10b of the valve 10 directed towards the intake duct 7 and opposite the surface iOa of this valve directed towards the combustion chamber. This avoids the disadvantages of the indirect injection devices of the prior art, while using a fuel circuit and an injector of a conventional type used in the case of indirect injection devices.

 The nose 14a of the injector 14 is never exposed, during operation of the engine, to high pressure and high temperature gases which may be present in the combustion chamber 5, during certain phases.

 In addition, the gasoline is injected into the combustion chamber 5, so as to come into contact with a hot surface, which promotes the vaporization of the gasoline and allows the formation of a very good quality fuel mixture. This results in an improvement in the stability and the quality of combustion during the operation of the engine and a reduction in the emission of polluting gases, in particular when the catalyst of the catalytic converter for treating exhaust gases is still cold and therefore ineffective.

 The injector 14 is controlled by an electronic device allowing perfectly controlled injection, during a phase during which the intake valve (s) is or are open and the exhaust valve (s) closed. The quantity of petrol entering the combustion chamber corresponds perfectly to the necessary quantity determined by the electronic engine control computer, depending on the operating conditions and the acceleration control.

 Such an operating mode is particularly advantageous, in the case of the operation of the engine in transient state.

 In a second mode of operation of the engine according to the invention, the injection of the fuel jet is carried out when the intake valve 10 is closed. The jet of gasoline strikes the interior surface 10b of the valve 10 and forms a liquid film covering this interior surface 10b. This embodiment is particularly advantageous in the case where the engine is operating in steady state, the intake valve then being sufficiently heated so that the gasoline vaporizes fairly quickly in contact with the external surface 10b of the valve. arrives in the chamber, when the inlet valve 10 is opened, in the heated state and already almost entirely vaporized, which is preferable in the case of the direct injection of a gas jet cold on contact with a wall of the combustion chamber. In addition, even if the quantity of petrol injected does not exactly correspond to the quantity of petrol entering the combustion chamber at a given instant, which results in a difference between the quantity of petrol required determined by the computer. engine control electronics and the quantity introduced into the combustion chamber, this difference does not have any drawback in stabilized regime, since we end up finding overall the whole quantity of gasoline injected into the combustion chamber, on a certain operating time.

 In stabilized regime, it is therefore preferable to carry out the injection while the intake valve is closed.

 During a cold start of the engine, the intake valve has not yet warmed up and, in this case, it is undesirable to carry out the injection when the intake valve is closed. It is therefore preferable, during cold starts of the engine, to perform the injection when the intake valve is open. The jet of petrol is then sent directly inside the combustion chamber and strikes the interior surface of the exhaust valve. The gasoline heats up more quickly, which improves the operating conditions of the engine and in particular reduces the emission of polluting gases, while the catalyst of the catalytic converter is still ineffective.

 During the accelerations imposed on the engine, that is to say during the transient phases, an injection in contact with the external surface of the intake valve does not allow the quantity of gasoline to be found in the combustion chamber injected at a determined time defined by the operating conditions of the engine, by the control computer.

 Since the transients have a very short duration, it is not possible to count on a duration effect to find the overall amount of gasoline injected into the combustion chamber.

 In this case, it is therefore preferable to carry out the injection with the intake valve open.

 The engine according to the invention therefore makes it possible to obtain the advantages of a direct injection, by avoiding the drawbacks of this type of injection and by using an injector and a low-pressure petrol circuit, as in the case of a conventional type indirect injection.

 Using specially programmed control means, it is also possible to go from direct injection under low pressure to indirect injection on the external surface of the intake valve.

 The engine according to the invention therefore has great flexibility, since it makes it possible to adapt the injection regime used to instantaneous engine operating conditions.

 The invention is not limited to the embodiment which has been described.

 Thus, the engine according to the invention can comprise cylinders with four valves. In this case, it is possible to associate a single injector with one of the intake valves or, on the contrary, two injectors each associated with an intake valve of the cylinder.

 The means of command-rn. Electronic injection systems can be of any type to adjust the quantities of fuel injected and the instant at which injection is triggered, during the cylinder's operating cycle. These control means must make it possible to obtain, as a function of the operating conditions of the engine and of the accelerations, an injection according to the first or according to the second mode described above. These control means must make it possible to switch from one operating mode to another, during changes in engine speed, for example during a transition from a transient to a stabilized speed.

 Finally, the engine according to the invention and the corresponding injection method can be used on any type of motor vehicle.

Claims (9)

 1.- Injection petrol engine comprising at least one cylinder (1) in which a combustion chamber (55, at least one intake duct (7) is provided, one end of which communicates with the combustion chamber through an orifice, at least one intake valve for closing or opening the orifice of the intake duct (7) and a petrol injector (14) opening into the intake duct (7), characterized in that the injector (14) is placed and directed so as to inject a gasoline jet (15), at a determined time in the engine operating cycle, towards the combustion chamber (5) and at the inside this chamber (5), in the event that the injection takes place when the intake valve (10) is opened.  2.- - engine according to claim I comprising at least one exhaust duct, one end of which communicates through an orifice with the combustion chamber (5) and at least one exhaust valve (12i for closing or opening the orifice of the exhaust duct (8) characterized in that the injector (14) is placed and directed so that the jet of fuel (15) strikes the interior surface (12a) of the exhaust valve 12 ) directed towards the combustion chamber (5), in the case where the injection takes place directly in the combustion chamber t5s, at the time of opening of the intake valve (10).  3.- Engine according to any one of claims 1 and 2, characterized in that the nozzle of the injector (14a) through which the fuel jet comes out (15) is disposed in the vicinity of the orifice of the conduit intake (7) and slightly set back from the intake duct (7).  4.- Engine according to any one of claims 1 to 3, characterized in that the injector (14) is a conventional type injector used in the case of an indirect injection into the intake duct of a engine, this injector (14) being connected to a low pressure fuel circuit.  5-- Method for injecting a jet of petrol (15) into an engine comprising at least one cylinder (1) in which a combustion chamber (5) is provided, at least one intake duct (7) one end of which communicates with the combustion chamber through an orifice, at least one intake valve (10) for closing or opening the orifice of the intake duct (7) and a fuel injector (14) opening into the intake duct, characterized by the fact that the injection of the fuel jet is controlled (is controlled while the intake valve (10) is in its open position, so that the jet (15) enters the chamber directly combustion (5) without coming into contact with the intake valve t  6.- Method according to claim 5, characterized in that the fuel jet (15) is directed so as to strike the inner surface (12a) of an exhaust valve (1) inside the combustion chamber (5).  7.- Method of injecting a jet of petrol (15) into an engine comprising at least one cylinder (1) in which a combustion chamber (5) is formed, at least one intake duct (7) one end of which communicates with the combustion chamber through an orifice, at least one intake valve (10) for closing or opening the orifice of the intake duct (7) and a fuel injector (14) opening into the intake duct, characterized in that the injection of the fuel jet (15) is controlled at a time when the intake valve (10) is in its closed position, the fuel jet (15) coming strike the external surface (rob) of the valve (10) directed towards the intake duct (7) and opposite its internal surface (lova) directed towards the combustion chamber (5).  8.- Method for injecting a jet of petrol (15) into an engine comprising at least one cylinder (1) in which a combustion chamber (5) is formed, at least one intake duct (7) one end of which communicates with the combustion chamber through an orifice, at least one intake valve (10) for closing or opening the orifice of the intake duct (7) and a fuel injector (14) opening into the intake duct, characterized in that the injection of the fuel jet (15) is carried out successively when the intake valve (is in its open position, the fuel jet (15) penetrating directly into the chamber combustion (5) without coming into contact with the intake valve (10) and, when the intake valve (10) is closed, the jet of fuel (15) striking the outer surface (10b) of the inlet valve (10) directed towards the inlet duct (7) and opposite its inner surface (10a) directed towards the combustion chamber mbustion, depending on the engine operating conditions.  9.- Method according to any one of claims 5 to 8, characterized in that the fuel jet (15) is injected under a low pressure close to 3 bars.