EP0152321A1 - Device for controlling the opening and closing of the combustion chamber of an internal-combustion engine - Google Patents

Abstract

1. Device for controlling the flow of the gas issuing from and flowing into the combustion chamber (2) of an internal combustion engine, constituted by a rotative valve cock or rotor (1) comprising at least one inner channel (3) or a lateral cut (24) defining transverse exhaust or inlet flow passages, respectively, a passage (5) directly connected to the combustion chamber (2), said valve cock (1) being enclosed in a transverse bore (4) into which opens the orifice of said passage formed in a sealing ring (6) which is placed in a bore (7) wherein it slides, said sealing ring (6) being applied onto the rotor (1) by a continuous contact surface (22) around the orifice of said passage (5) under the effect of the pressure prevailing within said combustion chamber (2) and surrounded by one or more sealing elements (11) such as sealing segments, while being provided with injection means (19, 23) for injecting oil onto said valve cock (1), characterized in that said sealing ring (6) is crossed through, at least at its periphery, by a pressure oil circuit (13, 14, 16) directed toward the oil collector and adapted to cool said ring (6), and in that said injection means (19, 32) which are connected to said oil circuit (13, 14, 16) cross axially at least a portion of the annular section of said ring (6) and open into an uninterrupted annular distributing groove (21) provided within the continuous contact surface (22) defined on a strip of small width along the general intersecting line of two cylinders, while opening at the interface (e) existing between said contact surface (22) and the outer surface (8) of said rotor (1).

Description

The present invention applies to a device for controlling the circulation of gases to and from a combustion chamber of an internal combustion engine, in particular of a two- or four-stroke cycle engine with reciprocating piston (s). ) or rotary (s), constituted by a plug or rotor comprising channels or a lateral cut defining respective transverse flow passages of exhaust or intake. In heat engines fitted with this type of distribution, the plug performs a continuous rotary movement synchronized with the rotation of the engine around an axis parallel to the axis of rotation of the engine to carry out the successive phases of the engine cycle by connecting to the 'exhaust then, if necessary, at the intake a passage directly connected to the combustion chamber.

According to a known embodiment of this type of motor (French patent applications 8,213,071 and 8,213,072) making it possible to rotate at high rotational speeds, the plug is contained in a transverse bore into which opens the directly connected orifice. to the combustion chamber and the intake and / or exhaust ports connected respectively to an exhaust manifold. The passage connected to the combustion chamber is arranged in a sealing ring housed in an applied bore, on the plug by a continuous sealing surface around the orifice connected directly to the combustion chamber, under the effect of the pressure prevailing in the combustion chamber, and surrounded by one or more sealing members such as segments, this ring which can slide in the bore and its stroke being limited, on one side, by the plug and, the other side, by a retaining shoulder.

Such combustion engines appear capable of delivering mass powers much higher than the known solutions and proven, in particular for small displacement engines, due to the absence of distribution parts subjected to an alternating movement generating a limit beat frequency. The most decisive advantage of this type of distribution is the possibility of having exhaust and intake ducts twice the diameter of a conventional valve system, which allows better filling. and therefore a higher specific power.

After a first in-depth experiment with rotary valve distribution devices, it turns out that these distribution rotor systems have drawbacks or operational faults which have not made it possible to exploit the advantages listed above.

Among these various drawbacks, mention may be made of the difficulties in ensuring the lubrication and cooling of the sealing elements, which causes excessive wear of the plug and of the sealing elements and elements, a high consumption of lubricant, and can lead to, in certain borderline cases, seizure of the bushel in its bore.

• - une dilution des gaz frais par les gaz d'échappement se traduisant par une mauvaise combustion et une pollution plus importante;
• - une introduction du mélange carburé dans les gaz d'échappement entraînant aussi une augmentation de la pollution et de la consommation spécifique en carburant.

Furthermore, when the rotary valve distribution is applied to four-stroke engines, there is no reduction in the specific fuel consumption compared to engines operating according to the two-stroke cycle. This overconsumption of fuel appears to be due to an insufficient separation of the ducts or of the intake and exhaust phases which leads to:

• - dilution of the fresh gases by the exhaust gases, resulting in poor combustion and greater pollution;
• - introduction of the fuel mixture into the exhaust gases also resulting in an increase in pollution and specific fuel consumption.

One of the aims of the present invention is precisely to overcome these defects of rotary distribution combustion engines in order to allow the large passage sections offered by this type of their distribution to be used without risking rapid wear and fuel consumption. exaggerated.

To this end, according to a first embodiment of the invention, the sealing ring is provided with means for injecting a lubricating and cooling fluid, such as oil, into the interface between the continuous sealing surface of the ring around the orifice and the external surface of the plug.

The means for injecting the fluid preferably consist, on the one hand, of an annular inlet chamber delimited between the periphery of the sealing ring and its bore and axially limited at each end by a seal d sealing interposed between the outer surface of the sealing ring and the bore and, on the other hand, of at least one supply passage having an outlet opening opening in said interface between the continuous sealing surface and the outside surface of the plug. At least the seal interposed between the outer surface of the sealing ring and its cooperating bore is then protected from the shot of the burnt gases of the combustion chamber by at least one protective segment interposed between the ring seal and its bore and between said seal and the combustion chamber.

The outlet opening of the supply passage may lead to a continuous annular distribution groove formed inside the contact surface of the sealing ring with the plug.

According to another embodiment of the device, the fluid injection means comprise means for regulating the flow of fluid such as the pressure drop caused by the reduced section of the fluid supply passages or by another means of loss. such as a throttle therein.

As a variant, the pressure drop means may consist of a porous annular cartridge opening onto said interface and interposed between this interface and at least one orifice for supplying the lubricating fluid under pressure and the cartridge is made of a material having good rubbing qualities with the outside surface of the plug, such as sintered bronze.

When the device for controlling the circulation of gases to and from the combustion chamber of the engine is applied to a heat engine operating according to the four-stroke cycle with the introduction of fuel prior to the suction of combustion air, means scrapers of the lubricating fluid injected into the interface are arranged around the intake orifice connecting the plug to the intake of combustion air and engine fuel, these scraping means being constituted by a sealing ring d intake arranged at the periphery of said intake orifice, coming into continuous support on the outer surface of the plug and capable of isolating the interior of the intake orifice from the interface between the plug and its bore to limit the entrainment of oil and / or liquid fuel on the surface of the plug in rotation. The sealing ring is, on the one hand, made of a soft material having good rubbing qualities with the surface of the plug such as plastic and, on the other hand, permanently pushed back on the surface of the plug under a substantially constant pressure by a spring.

According to another embodiment, the plug has two separate inlet and outlet passages respectively which are capable of successively opening both, by rotation of the plug, on the side of the combustion chamber, on the ring of sealing and, on the side opposite the combustion chamber, on outlet orifices which are each offset on the axis of the plug relative to the sealing ring, so as to reduce the entrainment of fuel at the surface of the rotating bushel and fuel entrained on intake into the intake passage formed inside the valve.

According to a particularly advantageous arrangement for polycylindrical engines, the separate intake or exhaust passages of two neighboring combustion chambers are formed in the plug by opening onto an orifice for communication with the intake or the exhaust which is common to two adjacent combustion chambers so as to reduce the number of openings to be provided on the outside face of the plug.

According to another arrangement applied to a heat engine operating according to the four-stroke cycle, the combustion chamber intake circuit includes means for removing fuel from the air drawn into the combustion chamber at the end of intake, in order to limit the amount of fuel introduced into the intake passage formed in the plug, and which has not entered the combustion chamber during the suction phase. In the case where the fuel is introduced by injection into the intake air, the abovementioned suppression means consist of stopping the injection of fuel clearly before the end of the suction phase.

In the case where the fuel is introduced into the combustion chamber via a carburetor, the abovementioned suppression means are then preferably constituted by at least one auxiliary passage of air rich in fuel such as an emulsion, formed in the bushel and cylinder head the combustion chamber and the auxiliary passage leads to the interface between the plug and its bore at a point such that it is closed by the rotation of the plug before the main opening (s) admission does not the self.

According to a variant of the device according to the invention, an end part of at least one supply member for one of the combustion elements, such as a spark plug for a spark-ignition engine or a injector and / or a heating plug for a diesel cycle engine, crosses in a sealed manner the cross section of the sealing ring to open into the passage which is connected to the combustion chamber, and the adjacent part of said end part is housed with annular clearance in a passage opening outwards from the wall of the cylinder head of the combustion engine.

This passage, which is connected to the combustion chamber, then plays the role of the main part of the combustion chamber,

According to another variant of the device according to the invention, the passage giving rise to the annular clearance is traversed by a cooling fluid.

Preferably, the refrigerant fluid consists of the lubricating and refrigerant fluid supplied by the injection means.

According to yet another variant of the device according to the invention, the passage giving rise to the annular clearance is extended towards the outside by an enlarged annular chamber, said annular chamber being closed by an elastic annular seal which is interposed between the inlet and the inner wall of said chamber and which delimits a cooling chamber through which the lubricating and refrigerant fluid supplied by the injection means.

This enlarged part allows a tool to access said supply member.

• - les figures 1 et 2 sont des vues en coupe et à grande échelle de deux modes de réalisation du système d'étanchéité selon l'invention entre un boisseau de distribution tournant et une chambre de combustion de moteur;
• - les figures 3a à 3c illustrent schématiquement les principales positions au cours d'un cycle moteur d'un système de distribution à boisseau appliqué à un moteur fonctionnant selon le cycle à quatre temps;
• - la figure 4 est une vue en coupe a grande échelle du système de distribution à boisseau représenté schématiquement sur les figures 3a à 3c et équipé d'un anneau d'étanchéité d'admission selon l'invention;
• - la figure 5 est une vue en coupe, toujours à grande échelle, d'un autre mode de réalisation du système de distribution à boisseau selon l'invention comportant des conduits d'admission et d'échappement séparés à l'intérieur du boisseau;
• - la figure 6 est une vue en coupe avec arrachements selon la ligne VI-VI de la figure 5, d'une partie du boisseau de distribution d'un moteur comportant plusieurs cylindres parallèles;
• - la figure 7 est une vue en coupe à grande échelle d'un système de distribution à boisseau selon l'invention dans lequel sont prévus des moyens d'appauvrissement en carburant de l'air aspiré en fin d'admission;
• - les figures 8 et 9 sont des coupes respectivement selon les lignes VIII-VIII et IX-IX du système de distribution représenté à la figure 7.
• - la figure 10 est une vue en coupe du système d'étanchéité selon l'invention comportant une bougie d'allumage débouchant dans la chambre de combustion.
• - la figure 11 est une vue en coupe du système d'étanchéité selon l'invention comportant une bougie d'allumage débouchant directement dans le passage de l'anneau d'étanchéité.

Other aims, advantages and characteristics of the control device according to the invention will appear on reading the description of various embodiments, given without limitation and with reference to the appended drawing where:

• - Figures 1 and 2 are sectional views on a large scale of two embodiments of the sealing system according to the invention between a rotating distribution valve and an engine combustion chamber;
• - Figures 3a to 3c schematically illustrate the main positions during an engine cycle of a plug distribution system applied to an engine operating according to the four-stroke cycle;
• - Figure 4 is a sectional view on a large scale of the valve distribution system shown schematically in Figures 3a to 3c and equipped with an intake sealing ring according to the invention;
• - Figure 5 is a sectional view, still on a large scale, of another embodiment of the valve distribution system according to the invention comprising separate intake and exhaust ducts inside the valve;
• - Figure 6 is a sectional view with cutaway along line VI-VI of Figure 5, of a portion of the distribution valve of an engine having several parallel cylinders;
• - Figure 7 is a sectional view on a large scale of a plug distribution system according to the invention in which there are provided means for depletion of fuel from the air sucked in at the end of intake;
• FIGS. 8 and 9 are sections respectively along lines VIII-VIII and IX-IX of the distribution system shown in FIG. 7.
• - Figure 10 is a sectional view of the sealing system according to the invention comprising a spark plug opening into the combustion chamber.
• - Figure 11 is a sectional view of the sealing system according to the invention comprising a spark plug opening directly into the passage of the sealing ring.

In FIGS. 1 and 2, a rotary plug 1 for distributing the exhaust from a combustion chamber 2 of a heat engine is shown at the time when its internal exhaust channel 3 is opened wide on the combustion chamber 2. The plug 1 turns, continuously and synchronously with the rotation of the engine, in a bore 4 and the channel exhaust 3 is connected to the combustion chamber 2 by a relatively large passage 5 formed in a sealing ring 6 which can slide freely in a bore 7 with an axis substantially parallel to that of the engine cylinder (not shown) or substantially perpendicular to the axis of rotation of the plug 1, so as to ensure good bearing of the contact surface of the ring 6 on the external surface 8 of the plug 1. The contact surface 22 between the ring 6 and the plug 1 is established on a strip of small width along the general line of intersection of two cylinders (the outer surfaces of the plug 1 and the ring 6 of different diameters and substantially perpendicular and concurrent axes. According to a known arrangement particularly effective because it provides the force of application of the sealing ring 6 on the plug 1 to the pressure to be sealed, the sealing ring 6 which moves with gentle friction in its bore 7 is applied on the external surface of the plug 1 by the single pressure prevailing in the combustion chamber 2 and acting on its annular section, increased if necessary by the thrust of a spring with low reaction force such as an elastic washer. The presence of this thrust spring (not shown) of the ring 6 on the plug 1 is not essential if there is only a slight clearance or interface i between the end 9 of the ring 6 of the side of the combustion chamber 2 and a retaining shoulder 10 formed at the end of the bore 7 receiving the ring 6. In addition, the temperature being relatively high in the interface i because of the proximity of the chamber 2 combustion, the holding over time of a spring member is very random. In order to eliminate leaks in the interface j between the outer surface of the ring 6 and the interior of its bore 7, a gun sealing segment 11 is disposed in a known manner in this interface j and is worn by a groove 12 preferably formed in the ring 6. The segment 11 also prevents overheating of the interface j in the direction of the plug 1 and the formation in this interface of deposits which would end up blocking the ring 6 in its bore 7 .

According to the invention, the sealing ring 6. is provided with means for injecting a lubricating and cooling fluid, preferably oil. engine lubrication system pressurized by the engine oil pump, in the interface e between the continuous sealing surface 22 (along the general line of orthogonal intersection of two cylinders of different diameters) around the orifice 3 formed in the plug 1 and the outer surface 8 of the plug 1.

According to the device represented in FIG. 1, the fluid injection means comprise a line 13 for supplying pressurized oil usually connected to the engine lubrication pump and opening onto an annular distribution chamber 14, delimited in the interface j between the periphery of the ring 6 and its bore 7 for example using a circular groove 15 formed at the periphery of the sealing ring 6. According to an arrangement favoring the cooling of the ring 6, the chamber 14 can be traversed by a large flow of pressurized oil going to another member to be lubricated or discharged by an outlet pipe 16. The chamber 14 is delimited in the interface j by two seals annular seals 17 and 18 disposed respectively on the side of the combustion chamber 2 and on the side of the plug 1. The annular seals 17 and 18 are preferably made of a resistant elastomeric material for seal housed by elasticity in grooves ring are formed at the outer surface of the ring 6 as the ^p d blow fire segment 11 and the flow of the oil protect against excessive temperature.

The oil distribution chamber 14 is connected to the interface e between the sealing surface of the ring 3 and the external surface 8 of the plug 1 by supply passages 19 made, preferably, by a longitudinal bore. in the thickness of the ring, connected to a transverse bore 20 from the bottom of the circular groove 15. The supply passages 19 can lead to the interface e directly by an outlet chamfer or else in an annular groove continuous distribution 21 formed inside the contact or sealing surface 22 of the ring 6, this in order to better distribute the oil in the interface e. It should be noted that the channel 6 formed inside the rotary valve 1 can be a channel for the admission of fresh gases (normally pressurized air or at atmospheric pressure) fueled or not, or else an exhaust channel combustion gases as described above and that the channel 3 can be replaced, as will be seen later, by a lateral notch successively filling, during the rotation of the plug, the intake passage functions then exhaust.

The operation of the device for controlling the circulation of gases from and / or to an engine combustion chamber, as shown in FIG. 1 will now be explained. As soon as the engine is set in rotation, it drives the plug 1 in synchronous rotation and it generates an oil pressure which is transmitted to the distribution chamber 14 and to the annular groove 21 to cause a thin blade of oil to flow between the sealing surface 22 of the ring 6 and the movable outer surface 8 of the plug 1.

The pressure prevailing in the combustion chamber 2 during the compression and combustion phases of the gases strongly applies the sealing surface 22 to the external surface 8 of the plug 1 and reduces the thickness of this oil blade to a minimum value. just sufficient to ensure an oil film between the surface of the plug 1 and the sealing surface 22. During the sweeping and suction phases (for running the engine according to the four-stroke cycle) where the pressure in the combustion chamber 2 is close to or slightly above atmospheric pressure (case of the supercharged engine), the friction hysteresis of the gun segment 11 of the ring 6 on the plug 1 maintains an effort of significant residual application of the ring 6 on the plug 1. This residual force limits oil leaks between the sealing surface 22 and the surface 8 of the plug at a rate just sufficient to ensure a continuous film of oil between the surface 8 of the bushel 1 and its guide bore 4. When the channel 3 inside the plug 1 is an exhaust channel, the oil leaks to the interior passage 3-5 are carried to the exhaust and therefore lost, while when the channel 3 is an intake channel, the oil leaks to the passage 5 are brought back into the combustion chamber 2 and thus at least partially reused.

Thanks to the continuous lubrication of the interface e, the wear of the sealing surface 22 of the ring 6 is reduced to a minimum value and the risks of seizure at high speed of the ring 6 on the plug 1 are deleted. The temperature of the surface of the plug 1 (moreover generally cooled internally by a longitudinal circulation of water) is considerably reduced and the seal between the plug and its bore 4 is ensured by an oil wedge. The circulation in diversion of the oil between the supply line 13 and the outlet line 16 provides vigorous cooling of the sealing ring 6 which could thus in some application cases be made of a relatively soft material of good rubbing quality such as molded plastic material with high resistance.

The sealing ring 6 as well as the plug 1 can be produced, preferably, in the different friction couples usually used in engines such as: cast iron / chrome, cast iron / cast iron, etc., but also in new composite materials , ceramics or other new products. A calibrated orifice (not shown) can be placed on the inlet pipe 13 or on the supply passages 19 in order to limit the flow of oil escaping from the interface e when the pressure drop caused by the passages is insufficient to limit the oil leakage rate.

In the embodiment shown in Figure 2, the elements identical to those shown in Figure 1 are given the same reference numbers. Unlike FIG. 1, the sealing ring 6 can be made of porous sintered metal with a sealing plating on the surfaces which should not give rise to oil exudation, or else as shown in the figure. 2, an annular ring or cartridge 23 made of porous sintered metal, such as bronze, is introduced or molded in a blind housing 19a formed longitudinally in the sealing ring 6. This porous ring 23 is connected by at least one lateral passage 20 to the oil pressure distribution chamber 14. The porous ring 23 thus functions as a pressure drop and oil distribution member in the interface e and as a good-quality rubbing member reducing the friction between the ring 6 and the rotary plug 1. This arrangement which appears suitable for cases where the speed of rotation of the plug 1 is moderate and where vigorous cooling of the sealing ring 6 is not required, reduces oil losses and is generally more economical to implement than the solution shown in Figure 1.

Figures 3a to 3c schematically show the most characteristic positions of a plug 1 provided, not with an internal channel, but with a notch 24 intended to ensure the distribution (suction and exhaust) of a combustion chamber 2 an internal combustion engine operating according to the four-stroke cycle. In FIG. 3a, it can be seen that the notch 24 connects the combustion chamber 2 of the engine (via a sealing ring of the type described in FIGS. 1 and 2 and not shown) to a suction pipe 25 provided with means introduction of fuel such as a carburetor or an injector, if the engine is running with a controlled ignition. In FIG. 3b, the plug 1 has turned counterclockwise and has closed both the suction pipe 25 and the exhaust pipe 26. It can be seen that the notch 24 of the plug 1 delimits with the bore 4 for guiding the plug 1 a passage chamber 27 of a significant volume and which is then isolated from the intake and the exhaust. The chamber 27 was filled during the intake phase with air relatively rich in fuel since it was sucked in after the walls of the suction pipe were saturated with liquid fuel. We see in Figure 3c that the air rich in fuel contained in the passage chamber 27 is completely discharged to the exhaust 26, in particular as a result of the arrival of the puff of exhaust gas at the time of setting communications (not shown) of the combustion chamber 2 with the chamber 27 when the edge 28 of the notch 24 opens onto the passage 5 connected to the combustion chamber 2.

Another source of overconsumption of fuel when the engine equipped with a rotary distributor valve operates according to the four-stroke cycle with fuel air supply, lies in the fact that the liquid fuel which flows on the suction walls and s' gradually evaporates in the direction of the combustion chamber, is entrained on the surface of the plug 1 in the direction of the exhaust 26 where the hot gases evaporate it and carry it away in pure exhaust in the exhaust with the film of oil deposited by the lubrication device shown in Figures 1 and 2.

Figure 4 shows, on a larger scale, a solution to reduce fuel and oil losses. Elements identical to those in FIGS. 1 to 3c are given the same reference numbers. In this embodiment, oil scraper means are arranged around the air intake orifice on the plug 1. The scraper means are constituted by an intake sealing ring 29 permanently applied to the surface 8 of the plug 1 by a spring 30. According to another arrangement of this embodiment, the fuel introduction means constituted here by a petrol injector 31 are adjusted so that the injection is cut off well before the end of the combustion air suction phase. The sealing ring 29 housed in the cooled cylinder head 32 of the engine and traversed by fresh intake gases are not subjected to high temperatures or significant pressure differences (overpressures and depressions are less than 1 bar) and as a result it can be made of a good quality plastic irottante such as Teflon.

The operation of the embodiment shown in Figure 4 is described below. The plug 1 rotates in synchronism with the motor and receives from the supply passages 19 and the distribution groove 21 an oil film which is driven on its surface 8. The oil film formed in the interface between the plug and the bore 4 is stopped by the sealing ring 29 substantially of the same width as the main sealing ring 6. The injection of fuel by the injector 31 begins as soon as the edge 28 of the notch 24 leads to the interior passage 33 of the suction ring 29 and stops well before the other edge 34 of the notch 24 reaches the right edge 35 of the passage 5 formed inside the ring 6 and does not cut off the intake. From the start of the injection of the fuel, part of it is vaporized in the jet of aspirated air while the other stops on the walls and is entrained towards the combustion chamber 2 by gradually evaporating . Thanks to the stop of the injection well before the end of the aspiration (while respecting the conditions of the almost stoichiometric mixture in the combustion chamber 2), the walls contain only a small quantity of liquid fuel when the intake is cut off and the passage chamber 27 is very poor in fuel. The liquid fuel which stagnates inside the passage 33 is stopped by the friction of the sealing ring 29 and cannot therefore be entrained towards the exhaust until the admission of air resumes at following suction cycle and does not carry into the combustion chamber 2 this liquid fuel which has largely evaporated during the rest of the engine cycle. The arrangements shown in FIG. 4 considerably reduce the quantity of fuel driven directly to the exhaust and allow a four-stroke cycle operating with a notched bushel and with reasonable consumption to be achieved while benefiting from significantly increased passage sections of the distribution by rotating bushel.

Another embodiment of the device for controlling the circulation of gases to and from an engine combustion chamber is shown in Figures 5 and 6 where the elements and members identical to those of the previous figures bear the same reference numbers. In this embodiment, the plug 1 has two separate inlet and outlet passages 36 and 37 respectively. Each of these two passages successively opens by rotation of the plug 1 on the side of the combustion chamber 2 on the ring d seal 6 and, on the opposite side, on orifices which are offset laterally with respect to the seal ring 6. The intake passage 36 opens on one side of the cylinder head onto the suction pipe 25 surrounded by its suction ring 29.

When the plug 1 has turned to come into full exhaust position, the exhaust passage 37 opens onto the passage 5 inside the ring 6 and onto the exhaust pipe 26 offset along the axis of the plug 1 with respect to the sealing ring 6.

According to the detail of the section of Figure 6, we see that inside the plug 1, the two intake passages 36 and 36a of two combustion chambers adjacent to an engine (in fact two parallel cylinders d 'a motor) lead to a common orifice 38 for communication with the intake pipe 25 common to the two cylinders.

This arrangement which also applies to exhaust pipes and orifices makes it possible to reduce the number of outlets to be provided in the plug 1 and the cylinder head 32 and which constitute as many zones of weakening of the mechanical resistance of these highly stressed members on mechanical and thermal plans.

Returning to FIG. 5, it is understood that during the rotation of the motor and of the plug 1, the passage chamber constituted by the suction pipe 36 or all the suction pipes 36-36a and 38, can trap air relatively rich in fuel but cannot be swept by the exhaust gases. The fuel contained in the suction passage 36 inside the plug 1 therefore remains in place until this passage 36 again reaches the suction position in order to inject it into the combustion chamber 2.

In the embodiment shown in Figures 7 to 9 and where the elements and bodies identical to those of the previous figures bear the same reference numbers, it is proposed to considerably reduce the fuel richness at the end of the suction period. To this end, the intake channel 25 shown in cross section at the Figure 8 and in longitudinal section in Figure 9, has two auxiliary passages 39 and 40 for supplying a fuel-rich mixture such as an air-gasoline emulsion obtained by injecting gasoline using an injector 31 (line 39 in Figure 9) or by an emulsion carburetor 41 (line 40 in Figure 9). When using petrol injection, a single auxiliary duct 39 is sufficient to ensure the correct metering of the fuel.

In this embodiment, as can be seen in the section of FIG. 8, during the rotation of the plug 1 during the intake phase of the four-stroke engine, the auxiliary conduits 39 and 40 of which are closed before the part enlarged 25a of the duct 25 is not and the air sucked at the end of suction on the wide section 25a does not contain fuel and sweeps the passage chamber 27 delimited by the notch 24 to deplete it of almost all the fuel liquid deposited on its walls, so that when this passage chamber is traversed by the exhaust gases, these entrain only a minute quantity of fuel thus unused towards the exhaust pipe 26.

Figures 10 and 11 illustrate the mounting of a supply member connecting the combustion chamber 2 to the outside and such as a spark plug 47 used when the engine is an internal combustion engine with positive ignition. In the case of a fuel injection engine such as a diesel cycle engine, the spark plug 42 may be replaced by a fuel injector or a glow plug. Elements and bodies identical to those of the preceding figures, of course, have the same reference numbers.

Referring to Figure 10, we see that the spark plug 42 is screwed into a thread 43 formed through a thin wall area 44 of the cylinder head 32 of the engine, so that its electrodes 45 (connected to the mass) and 46 protrude slightly inside the combustion chamber 2. When using an engine with a high compression ratio, most of the combustion chamber near the top dead center of the piston (not shown ), is constituted by the passage 5 of relatively large dimension formed in the sealing ring 6. When the spark plug 42 is placed in the position shown in Figure 10, the ignition of the fuel mixture is relatively poor because it does not start in a central position relative to the main volume of the combustion chamber at top dead center.

FIG. 11 illustrates in section an arrangement of the spark plug 42 (or where appropriate of a fuel injector or of a heating plug) which overcomes the drawbacks of the mounting solution shown in FIG. 10. L 'sealing ring 6 comprises between two supply passages 19 a thread 43 for receiving the end portion or base 47 of the spark plug 42 which, in the sealed mounting position through this thread crossing the cross section of the ring 6, projects by its electrodes 45 and 46 inside the passage 5 in the vicinity of the wall but substantially at the center of the main combustion chamber formed by this passage 5.

The spark plug rod 48 which constitutes the part adjacent to the base 47 crosses with play a relatively narrow passage 49 formed through the wall of the cylinder head 32. The passage 49 is connected to the outside by a bore 50 of larger diameter forming a annular chamber 51 into which the outlet pipe 16 opens. In order to close off the annular chamber 51, an elastic annular seal 53 is interposed between the wall of the bore 50 and the cylindrical insulator 52 of the outlet terminal 54 of the candle 42.

When the engine is running, a large flow of oil, preferably refrigerated beforehand, is brought in through line 13 and pressurizes the annular distribution chamber 14 to make it flow, via the inlet passages 19 , a low flow of lubricating oil in the interface e between the rotary plug 1 and the sealing surface 22 of the ring 6. At the same time, a greater flow of oil flows from the chamber 14 to the chamber 51 via the narrow passage 49. This oil flow, which is then evacuated to the tarpaulin, cools the ring 6 and the spark plug 42 by acting very effectively in the vicinity of the hottest part constituted by the base 47 and the electrodes. The position of the ring 6, relative to the rotary plug 1, is likely to vary in service as a result of the expansion of the ring 6, variable axial and radial pressure forces on this ring 6 and especially wear progressive sealing surface 22 of this ring in frictional contact with the surface 8 of the rotor 1, this wear varying the clearance i. The instantaneous (at each explosion) and progressive movements of the ring 6 do not disturb the sealing of the chamber 51 and the position of the spark plug in the cylinder head 32 thanks, on the one hand, to the play in the passage 49 and avoiding any contact between the cylinder head 32 and the spark plug rod 48 and, on the other hand, the elasticity of the annular seal 53 preferably made of an elastomeric material. Note that if the embodiment of FIG. 11 is applied to a diesel engine, the fuel injector can advantageously be cooled while the glow plug does not have to be or must be as little as possible. , which can be done by placing it in an insulating envelope.

The mounting device assembly system shown in Figure 11 performs mechanical and vibration decoupling between, on the one hand the sealing ring 6 which delimits most of the combustion chamber at the top dead center of the piston and, on the other hand, the cylinder head 32. Thanks to the damping properties of the elastomer of the seal 53 and of the annular seals 17 and 18, not only the possible vibrations of the ring 6 cannot be transmitted to the cylinder head and vice versa but, in addition, these vibrations are damped at their critical frequency by the large mass of elastomer of the joint 53.

For reasons of simplification, it is of course possible to mount the spark plug 42 on the thread 43 of the ring 6 outside the refrigerant circuit passing through the annular chamber 14. For this, it suffices that the chamber 14 is, by example, placed near the upper end (in the drawing) of the ring 6 and in the vicinity of the interface e, the spark plug base 47 being placed either in the vicinity of the middle of the height of the ring 6 , which is closer to combustion chamber 2.

Of course, the present invention is not limited to the embodiments, but it is susceptible of numerous variants accessible to those skilled in the art, without departing from the spirit of the invention. .

Claims (16)

1.- Device for controlling the circulation of gases to and from a combustion chamber of an internal combustion engine, in particular of a two- or four-stroke cycle engine with reciprocating or rotary piston (s) ), constituted by a plug or rotor comprising channels or a lateral cut defining respective transverse flow passages for exhaust or intake, this plug performing a continuous rotary movement synchronized with the rotation of the engine about a parallel axis to the axis of rotation of the engine to carry out the successive phases of the engine cycle by connecting to the exhaust or, if necessary to the intake, a passage directly connected to the combustion chamber, the plug being contained in a transverse bore into which opens the orifice connected directly to the combustion chamber and the intake and / or exhaust orifices connected respectively to an exhaust manifold, and the passage connected to the combustion chamber being fitted in a sealing ring which is housed in a bore, applied to the plug by a continuous sealing surface around the orifice connected directly to the combustion chamber under the effect of the pressure prevailing in the combustion chamber and surrounded by one or more sealing members such as segments, this ring being able to slide in the bore and its stroke being limited, on one side, by the plug and, on the other side, by a shoulder of retained, the sealing ring being provided with means for injecting a lubricating and cooling fluid, such as oil, characterized in that these injection means open into the interface (e) between the surface d 'continuous sealing (22) of the ring (6) around the orifice (3) and the outer surface (8) of the plug (1). 2.- Device according to claim 1, characterized in that the means for injecting the fluid consist, on the one hand, of an annular inlet chamber (14) delimited between the periphery of the sealing ring (6) and its bore (7) and limited axially at each end by a seal (17, 18) interposed between the outer surface of the seal ring and the bore (7) and, on the other part, at least one supply passage (19) having an outlet opening opening into said interface (e) between the continuous sealing surface (22) and the external surface (8) of the plug (1). 3.- Device according to claim 2, characterized in that at least one seal (17) interposed between the outer surface of the sealing ring (6) and its cooperating bore (7) is protected from the shot of the burnt gases of the combustion chamber (2) by at least one protective segment (11) interposed between the ring d seal (6) and its bore (7) and between said seal (17) and the combustion chamber (2). 4.- Device according to one of claims 2 or 3, characterized in that the outlet opening of the supply passage (19) opens onto a continuous annular groove (21) of distribution formed inside the surface contact (22) of the sealing ring (16) with the plug (1). 5.- Device according to one of claims 1 to 4, characterized in that the fluid injection means comprise means for regulating the fluid flow rate such as the pressure drop caused by the reduced section of the supply passages (19) of the fluid or by another means of pressure drop such as a throttle which is interposed therein. 6.- Device according to claim 5, characterized in that the pressure drop means consist of a porous annular cartridge (23) opening on said interface (e) and interposed between this interface (e) and at least one orifice d 'inlet (20) of the lubricating fluid, and in that the cartridge (23) is made of a material having good rubbing qualities with the outer surface (8) of the plug (1), such as sintered bronze. 7.- Device according to one of claims 1 to 6, applied to a heat engine operating according to the four-stroke cycle with introduction of fuel prior to the suction of combustion air into the combustion chamber, characterized in that that scraper means of the lubricating fluid injected into the interface (e) are disposed around the intake orifice connecting the plug (1) to the intake of combustion air and engine fuel, these scraper means being consisting of an inlet sealing ring (29) disposed at the periphery of said inlet orifice, coming into continuous abutment on the outer surface (8) of the plug (1) and capable of isolating the interior of the inlet port of the interface between the plug (1) and its bore (4) to limit the entrainment of oil and / or liquid fuel on the surface (8) of the plug (1) in rotation. 8.- Device according to claim 7, characterized in that the sealing ring (29) is, on the one hand, made of a soft material having good rubbing qualities with the surface of the plug such than plastic and, on the other hand, constantly pushed back on the surface of the plug under a substantially constant pressure by a spring (30). 9.- Device according to one of claims 1 to 8, characterized in that the plug (1) comprises two separate passages (36, 37) of intake and respectively of exhaust which are capable of opening successively both by rotation of the plug (1), on the side of the combustion chamber (2), on the sealing ring (6) and, on the side opposite to the combustion chamber (2), on outlet orifices which are each offset on the axis of the plug (1) relative to the sealing ring (6), so as to reduce the entrainment of fuel at the surface of the plug and of the fuel entrained at the intake in the passage of inlet (27) formed inside the plug. 10.- Device according to claim 9, characterized in that the separate passages (36, 37) intake or exhaust of two neighboring combustion chambers are formed in the plug by opening on a communication orifice (38) with the intake or exhaust which is common to the two adjacent combustion chambers so as to reduce the number of openings to be provided on the outside face of the plug. 11.- Device according to one of claims 1 to 10, applied to a heat engine operating according to the four-stroke cycle, characterized in that the intake circuit of the combustion chamber (2) comprises means for removing the fuel in the air sucked into the combustion chamber at the end of intake, in order to limit the amount of fuel introduced into the intake passage (27) formed in the plug and which has not entered the combustion chamber (2) during the aspiration phase. 12.- Device according to claim 11, characterized in that, in the case where the fuel is introduced by injection into the intake air, the suppression means are constituted by stopping the fuel injection significantly before the end of the aspiration phase. 13.- Device according to claim 11 or 12, characterized in that the suppresion means consist of at least one auxiliary passage (39, 40) of air rich in fuel such as an emulsion, formed in the plug (1 ) and the cylinder head (32) of the combustion chamber and in that the auxiliary passage (39, 40) opens onto the interface between the plug (1) and its bore (4) at a point such that it is closed by the rotation of the plug (1) before the main intake opening (s) (25) is not. 14.- Device according to any one of claims 1 to 13, characterized in that an end portion (45, 46, 47) of at least one supply member of one of the combustion elements, such that a spark plug (42) for a positive-ignition engine or an injector and / or a heating plug for a diesel cycle engine, passes through the cross section of the sealing ring (6) to open into the passage (5) which is connected to the combustion chamber, and in that the adjacent part (48) of said end part is housed with an annular clearance in a passage (49) opening towards the outside of the cylinder head wall (32) of the combustion engine. 15.- Device according to claim 14, characterized in that the passage (49) giving rise to the annular clearance is traversed by a coolant. 16.- Device according to claim 15, characterized in that the cooling fluid is constituted by the lubricating and cooling fluid supplied by the injection means (19). 17.- Device according to one of claims 14 to 16, characterized in that the passage (49) giving rise to the annular clearance is extended outwards by an enlarged annular chamber (52), which is closed by an annular seal elastic (53) which is interposed between the supply member (42) and the interior wall (50) of said chamber (51) and which delimits a cooling chamber (14, 49, 51) through which the lubricating fluid passes and refrigerant supplied by the injection means (19).

Images