EP0104541A2 - Process for the transformation of thermal energy into mechanical energy by means of a combustion engine, and the engine - Google Patents

Abstract

This process is characterized by a cycle whose number of times is greater than four; at least four of these times being: a. the compression of air contained in the variable volume chamber, inside a preheating chamber; b. the expansion of the variable volume chamber by the expansion of hot air contained in the preheating chamber; vs. compression of the expanded hot air contained in the variable volume chamber in a combustion chamber where a fuel is introduced causing the combustion of the mixture; d. the expansion of the variable volume chamber by the expansion therein of high temperature and high pressure combustion gases from the combustion chamber. The motor comprises a body (23) inside which a movable member (25) moves defining a variable volume chamber (29). The body (23) has an intake duct (35) and an exhaust duct (34). This engine comprises an air preheating chamber (41) whose inlet and outlet communicate, via a distribution member (36), alternately with the variable volume chamber (29). This engine also comprises a combustion chamber (44), provided with a fuel distributor, the inlet and outlet of which communicate, via the distribution member (36), alternately with the variable volume chamber. (29).

Description

There are many types of internal or external combustion and / or internal combustion engines which can be classified into two main categories, two-stroke engines and four-stroke engines.

Two-stroke engines have the advantage of having a high ratio of active time to inactive time, equal to 1/2, but on the other hand due to their design the fuel consumption is higher than in a four-stroke engine.

Four-stroke engines are more fuel efficient, but have a relatively complicated timing system and, above all, have an unfavorable active time to inactive time ratio of 1/4. The calorie losses through the walls are higher than in a two-step process.

The present invention relates to an engine whose cycle differs from existing combustion engines which makes it possible to increase the ratio between active and inactive times compared to four-stroke engines and to be more fuel efficient. It allows the use of all fuels and the actual thermal efficiency is higher than conventional two-stroke and four-stroke. Losses from exhaust gases and cooling water are lower.

In diesel engines a high compression ratio is necessary for the ignition of the diesel / air mixture. On the other hand, the almost instantaneous ignition of the mixture is at the origin of knocking and noise phenomena. This type of engine requires a particularly robust and more expensive construction than a petrol engine. The present invention makes it possible to use diesel fuel while by overcoming these drawbacks.

The production of the motor according to the invention is made possible by a new process for transforming thermal energy into mechanical energy which is defined in claim 1.

The new engine according to the invention includes the characters listed in claim 12.

• Les figures 1 à 6 sont des coupes schématiques transversales d'un moteur rotatif à six temps illustrant les positions relatives des parties mobiles et fixes du moteur pour la fin de chacun des six temps constituant un cycle complet de fonctionnement.
• Les figures 7 à 12 illustrent en coupe schématique transversale les six temps d'une exécution du moteur à piston à déplacement linéaire.
• La figure 13 est une coupe longitudinale du moteur illustré aux figures 7 à 12.
• La figure 14 est une coupe partielle transversale d'une variante du moteur illustré aux figures 7 à 13.
• La figure 15 illustre en coupe longitudinale une troisième forme d'exécution du moteur.

The accompanying drawing illustrates schematically and by way of example three embodiments of the engine according to the invention.

• Figures 1 to 6 are schematic cross sections of a six-stroke rotary engine illustrating the relative positions of the movable and fixed parts of the engine for the end of each of the six times constituting a complete cycle of operation.
• Figures 7 to 12 illustrate in schematic cross section the six times of an execution of the linear displacement piston engine.
• FIG. 13 is a longitudinal section of the engine illustrated in FIGS. 7 to 12.
• FIG. 14 is a partial cross-section of a variant of the engine illustrated in FIGS. 7 to 13.
• FIG. 15 illustrates in longitudinal section a third embodiment of the engine.

The present method of converting thermal energy into mechanical energy makes use of a combustion engine comprising a body provided with a suction duct and an exhaust duct and having at least one movable member displaceable relative to this body and defining a variable volume chamber.

This method comprises an operating cycle whose number of active and inactive times is greater than four and preferably equal to six.

• a. la compression d'air contenu dans la chambre à volume variable, par réduction du volume de celle-ci, à l'intérieur d'une chambre de préchauffage ;
• b. l'expansion de la chambre à volume variable par la détente d'air chaud contenu dans la chambre de préchauffage ;
• c. la compression, par une réduction du volume de la chambre à volume variable, de l'air chaud détendu qui s'y trouve dans une chambre de combustion dans laquelle on introduit un combustible provoquant la combustion du mélange ainsi obtenu ;
• d. l'expansion de la chambre à volume variable par la détente dans celle-ci de gaz de combustion à haute température et haute pression provenant de la chambre de combustion.

Among the times of this cycle comprising more than four beats, we always find at least the following four beats:

• at. compressing the air contained in the variable volume chamber, by reducing the volume thereof, inside a preheating chamber;
• b. the expansion of the variable volume chamber by the expansion of hot air contained in the preheating chamber;
• vs. the compression, by reducing the volume of the variable-volume chamber, of the expanded hot air which is there in a combustion chamber into which a fuel is introduced causing the combustion of the mixture thus obtained;
• d. the expansion of the variable volume chamber by the expansion therein of high temperature and high pressure combustion gases from the combustion chamber.

• e. l'introduction d'air, par le conduit d'aspiration, dans la chambre à volume variable lors d'une augmentation du volume de cette chambre ; et
• f. l'expulsion, par le conduit d'échappement, par une réduction du volume de la chambre à volume variable, du gaz de combustion détendu contenu dans cette chambre.

In the case of a six-stroke operating cycle, the method also comprises the following two times:

• e. the introduction of air, through the suction duct, into the variable volume chamber during an increase in the volume of this chamber; and
• f. the expulsion, through the exhaust duct, by reducing the volume of the variable-volume chamber, of the expanded combustion gas contained in this chamber.

This process therefore comprises two active or motor times which are the expansion of the variable volume chamber by compressed hot air (time b) and the expansion of this variable volume chamber by a high temperature combustion gas and high pressure (time d).

This process therefore includes a ratio between active and inactive times equal to 1/3 and an escape every six times only.

The method described comprises two variants according to the succession of times a to f in a complete operating cycle. In the first variant the times of a cycle follow one another as follows: e, a, b, c, d, f while in the second variant this succession of times is: e, a, d, f, b, vs.

According to this process, the compressed air is heated in the preheating chamber during time "a" by a heat exchange between the combustion chamber and the preheating chamber.

In the second variant of the process, it is noted that the air and the combustion gas remain in the preheating and combustion chambers respectively for a period of time corresponding to the duration of approximately two successive times of the process. This is advantageous, because on the one hand the combustion can be done more slowly by limiting the explosion phenomenon and on the other hand this combustion can be done more completely. By this fact, the emission of harmful gases and smoke is reduced. Combustion taking place in a chamber independent of the variable volume chamber, violent forces on the moving parts of the engine are eliminated, which represent a significant drawback of the diesel system. The construction is lightened and the operation quieter.

In addition, in this second variant, the residence time of the air in the preheating chamber being longer, its temperature and its pressure are increased, which allows better efficiency to be obtained.

According to this method, any undue overpressure in the combustion chamber is avoided by adjusting the pressure of the preheating chamber as a function of that prevailing in the combustion chamber. When the pressure increases above a determined value in the combustion chamber, one evacuates a

part of the air contained in the preheating chamber towards the intake duct.

To obtain optimum preheating of the air contained in the preheating chamber, this chamber is located at least partially inside the combustion chamber. Air circulation takes place in one direction only in the preheating chamber, the latter having an inlet and an outlet.

The introduction respectively expulsion into and out of the variable volume chamber of fresh air, hot air and combustion gases is carried out as will be seen later using a device distribution by lights or by means of controlled valves.

The first embodiment of the engine illustrated schematically in Figures 1 to 6, operates according to the second variant of the method described, that is to say that the succession of times in a complete cycle is: e, a, d, f , b, c.

This engine comprises a static body 1 comprising an ambient air intake duct 2. This body 1 also comprises an exhaust duct 4. This body has the general shape of a circular ring, the ducts 2 and 4 open out at both on its outer periphery and on its inner periphery. The intake 5 and exhaust 6 openings opening onto the internal periphery of the static ring 1 are located one opposite the other, ie offset by approximately 180 °.

The body or static ring 1 comprises a preheating chamber 7 having an inlet lumen 8 opening onto the internal periphery of the body 1 between the intake 5 and exhaust 6 ports, approximately 60 ° after the intake lumen counterclockwise. The outlet light 9 from this preheating chamber 7 opens onto the internal periphery of the body 1, approximately 60 ° after the exhaust light always in the opposite direction. clockwise.

This body 1 also includes a combustion chamber 10, the inlet lumen 11 of which is located between the intake ports 5 and the outlet lumen 9 of the preheating chamber 7. The outlet lumen 12 of this combustion chamber 10 opens onto the internal periphery of the body 1 between the inlet lumen 8 of the preheating chamber 7 and the exhaust lumen 6.

A fuel injector 13 opens into a throttled part 14 of this combustion chamber and makes it possible to deliver fuel to this chamber either by means of an injection pump or by venturi effect due to the circulation of air in this room.

A spark plug 3 also opens into this combustion chamber 10 for igniting the gas mixture when the engine is started when cold.

A passage 15 connects the inlet of the preheating chamber 7 to the suction port 5. A controlled valve 16 generally closes this passage 15. This valve 16 is controlled by the pressure prevailing in the combustion chamber 10, detected at using a detector 17 and an electronic control device 17a.

The movable part of the engine comprises a drive shaft 18 connected to two oscillating pistons 19 and 19a inside a distribution ring 20 rotatably mounted inside the body l. This movable part of the engine is produced for example in the manner described in FIGS. 1 to 6 of the CH patent (application No. 1.834 / 82) and is arranged so that the pistons 19, 19a perform three alternations, that is to say six movements of va back and forth, during a revolution of the motor shaft 18 and of the distribution ring 20.

These oscillating pistons 19, 19a define two chambers 21, 2la with variable volume working in opposition.

The distribution ring 20 has two opposite openings 22, 22a passing through, located in a bisector plane of the chambers 21, 2la and communicating continuously with them. These two orifices are also located in a plane transverse to the motor shaft 18.

• 1. Pendant la rotation de la partie mobile du moteur de sa position illustrée à la figure 6 jusqu'à sa position illustrée à la figure l, l'ouverture 22 de l'anneau de distribution 20 s'est déplacée en regard de la lumière d'admission 5 et la chambre 21 a passé de son volume minimum à son volume maximum aspirant de l'air atmosphérique par le conduit d'admission. Ceci correspond au temps "e" d'admission d'air.
• 2. Pendant une rotation subséquante de la partie mobile du moteur de sa position illustrée à la figure 1 jusqu'à sa position illustrée à la figure 2, la chambre 21 diminue de volume provoquant la compression de l'air qui y est enfermé et le transfert de cet air comprimé dans la chambre de préchauffage 7 pendant le temps où l'orifice 22 est en regard de la lumière d'entrée 8 de cette chambre de préchauffage 7. Ceci correspond au temps "a" de compression de l'air. Avant ce transfert dans la chambre de préchauffage 7 celle-ci s'est vidée par l'orifice 22a dans la chambre 2la provoquant son expansion (temps b).
• 3. Pendant la rotation de la partie mobile du moteur de sa position illustrée à la figure 2 jusqu'à sa position illustrée à la figure 3, l'orifice 22 de l'anneau de distribution 20 passe devant la lumière de sortie 12 de la chambre de combustion 10 et le gaz de combustion à haute température et à haute pression entre dans la chambre 21 et provoque son expansion et par cela la rotation de l'arbre moteur 18. Ceci correspond au temps "d" d'expansion de la chambre à volume variable sous l'action des gaz de combustion.
• 4. Pendant la rotation de la partie mobile du moteur de sa position illustrée à la figure 3 à celle illustrée à la figure 4, les gaz de combustion détendus sont expulsés par réduction de volume de la chambre 21 dans le conduit d'échappement 4 par l'intermédiaire de l'ouverture 22 qui est en regard de la lumière d'échappement 6. Ceci correspond au temps "f", échappement.
• 5. Pendant la rotation de la partie mobile du moteur de sa position illustrée à la figure 4 à celle illustrée à la figure 5, l'orifice 22 de l'anneau de distribution 20 passe devant la lumière de sortie de la chambre de préchauffage 7 et l'air comprimé contenu dans celle-ci, chauffé par échange de chaleur avec la chambre de combustion 10, entre dans la chambre à volume variable 21, se détend dans celle-ci en provoquant son expansion. Ceci correspond au temps "b", détente de l'air préchauffé.
• 6. Pendant la rotation de la partie mobile du moteur de sa position illustrée à la figure 5 jusqu'à celle illustrée à la figure 6, la chambre à volume variable comprime l'air chaud détendu puis l'envoie dans la chambre de combustion lorsque l'orifice 22 de l'anneau de distribution 20 passe devant la lumière d'entrée 11 de la chambre de combustion 10. Cet air chaud comprimé entrant dans la chambre de combustion 10 reçoit une dose de combustible adéquate provenant de l'injecteur 13. La pression et la température régnant dans cette chambre de combustion provoquent l'auto-allumage du mélange et sa combustion. Ceci correspond au temps "c", combustion. Au démarrage du moteur à froid cet allumage est obtenu par la bougie 3. Avant l'envoi de cet air chaud dans la chambre de combustion 10, l'orifice 22a a passé devant la lumière de sortie 12 de la chambre de combustion 10 dont le gaz à haute pression a provoqué l'expansion de la chambre 2la (temps d).

The operation of the engine described is as follows:

• 1. During the rotation of the movable part of the motor from its position illustrated in FIG. 6 to its position illustrated in FIG. 1, the opening 22 of the distribution ring 20 has moved opposite the light 5 and the chamber 21 has gone from its minimum volume to its maximum volume sucking atmospheric air through the intake duct. This corresponds to the air intake time "e".
• 2. During a subsequent rotation of the movable part of the motor from its position illustrated in FIG. 1 to its position illustrated in FIG. 2, the chamber 21 decreases in volume causing the compression of the air which is enclosed therein and the transfer of this compressed air into the preheating chamber 7 during the time when the orifice 22 is opposite the inlet lumen 8 of this preheating chamber 7. This corresponds to the time "a" of air compression. Before this transfer to the preheating chamber 7, the latter is emptied through the orifice 22a in the chamber 2la causing it to expand (time b).
• 3. During the rotation of the movable part of the motor from its position illustrated in FIG. 2 to its position illustrated in FIG. 3, the orifice 22 of the distribution ring 20 passes in front of the outlet light 12 of the combustion chamber 10 and the combustion gas at high temperature and at high pressure enters the chamber 21 and causes its expansion and thereby the rotation of the motor shaft 18. This corresponds to the time "d" of expansion of the variable volume chamber under l action of combustion gases.
• 4. During the rotation of the movable part of the engine from its position illustrated in FIG. 3 to that illustrated in FIG. 4, the expanded combustion gases are expelled by reduction of volume of the chamber 21 in the exhaust duct 4 by through the opening 22 which is opposite the exhaust port 6. This corresponds to the time "f", exhaust.
• 5. During the rotation of the mobile part of the engine from its position illustrated in FIG. 4 to that illustrated in FIG. 5, the orifice 22 of the distribution ring 20 passes in front of the outlet lumen of the preheating chamber 7 and the compressed air contained therein, heated by heat exchange with the combustion chamber 10, enters the variable-volume chamber 21, expands therein causing it to expand. This corresponds to time "b", relaxation of the preheated air.
• 6. During the rotation of the movable part of the engine from its position illustrated in FIG. 5 to that illustrated in FIG. 6, the variable volume chamber compresses the expanded hot air and then sends it into the combustion chamber when the orifice 22 of the distribution ring 20 passes in front of the inlet lumen 11 of the combustion chamber 10. This hot compressed air entering the combustion chamber 10 receives an adequate dose of fuel from the injector 13. The pressure and temperature prevailing in this combustion chamber cause the mixture to self-ignite and burn. This corresponds to time "c", combustion. When the engine is started when cold, this ignition is obtained by the spark plug 3. Before sending this hot air into the combustion chamber 10, the orifice 22a has passed in front of the outlet light 12 from the combustion chamber 10, the high pressure gas caused the expansion of chamber 2la (time d).

The cycle begins again and continues like this. In the engine shown diagrammatically, the pistons 19, 19a define them variable volume chambers 21, 2la working in opposition, but each carrying out for itself the succession of the above operations 1 to 6, offset by approximately 180 °.

It should be noted that during the expansion times b and d, the preheating-combustion chambers respectively may only be partially emptied so as to maintain a given pressure there. These chambers can thus have a volume greater than the difference between the maximum and minimum volumes of the variable volume chamber. This increases the heat exchange between the combustion gases and the compressed air and ensures better regularity of operation at all speeds.

This engine combines simplicity, performance, economy and pollution reduction. In fact, it can be seen that by six-stroke cycle, two strokes are driven, the expansion of the preheated air and the expansion of the combustion gases; this therefore increases the performance of such an engine compared to a four-stroke engine.

The compressed hot air sent to the combustion chamber remains in this chamber for 1/3 of the operating cycle, which is longer than is the case in a four-stroke engine. This results in better combustion of the gas and a reduction in the emission of harmful gases and smoke.

In addition, when the pressure exceeds the desired pressure in the combustion chamber, part of the air contained in the preheating chamber is transferred to the intake port, preheating the intake fresh air.

This engine can run on any petrol, diesel fuel, etc. In fact, the temperature of the combustion chamber can be kept at a high value during the entire operating cycle. It is even possible to provide elements inside this chamber which remain incandescent to ensure self-ignition of the fuel.

Because the combustion takes place more slowly than in a four-stroke engine and, moreover, the combustion chamber is in a monolytic block of the engine and that finally the pressure prevailing in this chamber is controlled, the construction of a such a diesel engine can be as light as that of a four-stroke petrol engine.

Always by the fact that the pressure prevailing in the combustion chamber is limited, or even controlled in particular as a function of the power required and therefore of the quantity of fuel which is introduced therein, the volume of combustion gas which it contains can be dosed so that after expansion in the variable volume chamber, these expanded combustion gases are at a pressure only slightly above atmospheric pressure. Therefore, the exhaust noise of such an engine is greatly reduced.

The thermal efficiency of this engine can also be increased since it is possible to work at high temperature in the combustion chamber without having to cool it down considerably. In fact, this chamber can be coated with ceramic, as can the lights and the orifices 22 to allow operation at high temperature. Seals are provided between the moving parts.

The power of the engine and consequently its number of revolutions is controlled by the quantity of fuel introduced into the combustion chamber, the intake of fresh air being practically constant.

The second embodiment of the engine illustrated in FIGS. 7 to 13 comprises a body 23 comprising at least one cylinder 24 in which a piston 25 moves in a rectilinear reciprocating movement. This piston 25 is connected to the crankpin 26 of a crankshaft 27 by a connecting rod 28. The crankshaft 27 constitutes the engine shaft. The piston 25 defines with the cylinder 24 a chamber 29 with variable volume.

A rotor 30 is rotatably mounted in the upper part of the body 23 and is integral with an axis 31 carrying at one of its ends a toothed wheel 32. This toothed wheel 32 is connected to a pinion 33 secured to the shaft. engine. A ratio of 1/3 of this kinematic connection causes the rotor 30 to rotate three times slower than the crankshaft 27.

The upper part of the body comprises an intake duct 35 and an exhaust duct 34 opening on the one hand to the lateral external wall of the body 23 and on the other hand to the lateral wall of the housing of the body in which the rotor 30.

A distribution member is constituted here by an opening 36 formed in the body 23 and connecting the variable-volume chamber 29 to the periphery of the housing receiving the rotor 30. The body 23 also contains an ignition member, such as a candle 37 emerging in a cavity 38 open on the housing receiving the rotor 30. The spark plug 37 is offset by approximately 60 ° in a clockwise direction with respect to the opening 36. The body 23 also includes a fuel injector 39 opening into a cavity 40 open on the periphery of the housing containing the rotor 30.

The rotor 30 contains a preheating chamber 41 constituted by a diametral channel, the two ends of which, the inlet 42 and the outlet 43 open onto the periphery of the rotor 30.

This rotor 30 also contains a combustion chamber 44, at least partially surrounding the preheating chamber 41, the inlet 45 and the outlet 46 of which open onto the periphery of the rotor 30.

This rotor also has an intake passage 47, one end of which opens onto the periphery of the rotor and the other onto the lateral face of the latter and cooperates with the intake duct 35 of the body 23. Finally, the rotor has an exhaust passage 48, one end of which opens onto the periphery of the rotor 30, while the other end opens onto the lateral face of the rotor and cooperates with the exhaust duct 34 of the body.

All the orifices opening onto the periphery of the rotor 30 are adapted to cooperate successively, during the rotation of the rotor, with the dispensing opening 36.

This engine also operates according to the method described above and comprises the six times a to f, the succession of which is: e, a, d, f, b, c as for the first embodiment of the engine illustrated in FIGS. 1 to 6.

• 1. Pendant que le piston 25 descend, la chambre 29 augmente de volume, et que le rotor passe de sa position illustrée à la figure 12 jusqu'à la figure 7, le passage d'admission 47 relie l'ouverture de distribution 36 au conduit d'admission 35 du corps 23 permettant un remplissage de la chambre 29 avec de l'air frais atmosphérique. Ceci correspond au temps "e" d'admission d'air. Pendant que le rotor 30--est dans sa position illustrée à la figure 7, fin d'admission, la sortie 46 de la chambre de combustion coïncide avec l'évidement 38. Ainsi, si le mélange combustible contenu dans cette chambre ne s'allume pas par auto- allumage, il est possible de l'allumer par une étincelle.
• 2. Pendant la remontée du piston 25, réduisant le volume de la chambre 29, et que le rotor 30 passe de sa position illustrée à la figure 7 jusqu'à celle illustrée à la figure 8, l'air contenu dans la chambre 29 est comprimé puis envoyé dans la chambre de préchauffage 41 lorsque son entrée 42 est en coin- cidence avec l'ouverture de distribution 36. Ceci correspond au temps "a", compression de l'air.
• 3. Pendant que le rotor 30 passe de sa position illustrée à la figure 8 à celle illustrée à la figure 9, la sortie 46 de la chambre de combustion passe devant l'ouverture de distribution 36 permettant l'expansion du gaz de combustion à haute température et à haute pression dans la chambre 29 et forçant le piston 25 vers le bas. Ceci correspond au temps "d" expansion de la chambre à volume variable sous l'action des gaz de combustion.
• 4. Pendant la remontée subséquente du piston 25, réduisant le volume de la chambre 29, et que le rotor passe de sa position illustrée à la figure 9 à celle illustrée à la figure 10, la chambre à volume variable 29 est reliée par l'ouverture 36 et le passage 48 au conduit d'échappement 34. Ceci correspond au temps "f", échappement. Pendant que le rotor 30 est dans sa position illustrée à la figure 10, correspondant à la fin de l'échappement, l'injecteur 39 introduit une quantité déterminée de carburant dans la chambre de combustion dont l'entrée 45 coïncide avec l'évi-15 dement 40.
• 5. Pendant que le rotor 30 passe de sa position illustrée à la figure 10 à celle illustrée à la figure 11, la sortie 43 de la chambre de préchauffage 41 passe devant l'ouverture 36 et l'air comprimé préchauffé qu'elle contient se détend dans la chambre 29 provoquant la descente du piston 25. Ceci correspond au temps "b", détente de l'air préchauffé.
• 6. Pendant la remontée subséquente du piston 25, réduisant le volume de la chambre 29, le rotor a passé de sa position illustrée à la figure 11 à celle illustrée à la figure 12, et pendant que l'entrée 45 de la chambre de combustion 44 passe devant l'ouverture 36, l'air chaud détendu contenu dans la chambre à volume variable 29 est comprimé dans la chambre de combustion 44. Cet air chaud comprimé entrant dans la chambre de combustion reçoit une dose adéquate de combustible provenant de l'injecteur 39. La pression et la température régnant dans cette chambre de combustion provoquent l'auto-allumage du mélange et sa combustion. Ceci correspond au temps "c", combustion. Les moments de l'injection et de l'allumage seront déterminés pour donner des conditions de rendements optimum pendant le temps de séjour de l'air chaud comprimé dans la chambre de combustion.

The operation of this second embodiment of the engine is as follows:

• 1. As the piston 25 descends, the chamber 29 increases in volume, and the rotor passes from its position illustrated in FIG. 12 to FIG. 7, the intake passage 47 connects the distribution opening 36 to the inlet duct 35 of the body 23 allowing the chamber 29 to be filled with fresh atmospheric air. This corresponds to the air intake time "e". While the rotor 30 - is in its position illustrated in FIG. 7, end of intake, the outlet 46 of the combustion chamber coincides with the recess 38. Thus, if the combustible mixture contained in this chamber does not ignite by self-ignition, it is possible to ignite it with a spark.
• 2. During the ascent of the piston 25, reducing the volume of the chamber 29, and as the rotor 30 passes from its position illustrated in FIG. 7 to that illustrated in FIG. 8, the air contained in the chamber 29 is compressed then sent to the preheating chamber 41 when its inlet 42 is in coincidence with the dispensing opening 36. This corresponds to the time "a", compression of the air.
• 3. While the rotor 30 passes from its position illustrated in FIG. 8 to that illustrated in FIG. 9, the outlet 46 of the combustion chamber passes in front of the distribution opening 36 allowing the expansion of the combustion gas at high temperature and high pressure in the chamber 29 and forcing the piston 25 downwards. This corresponds to the time of "expansion" of the variable volume chamber under the action of the combustion gases.
• 4. During the subsequent raising of the piston 25, reducing the volume of the chamber 29, and as the rotor passes from its position illustrated in FIG. 9 to that illustrated in FIG. 10, the variable volume chamber 29 is connected by the opening 36 and the passage 48 to the exhaust duct 34. This corresponds to the time "f", exhaust. While the rotor 30 is in its position illustrated in FIG. 10, corresponding to the end of the exhaust, the injector 39 introduces a determined quantity of fuel into the combustion chamber, the inlet 45 of which coincides with the evi- 15 dement 40.
• 5. While the rotor 30 passes from its position illustrated in FIG. 10 to that illustrated in FIG. 11, the outlet 43 of the preheating chamber 41 passes in front of the opening 36 and the preheated compressed air it contains relaxes in chamber 29 causing the piston 25 to descend. This corresponds to time "b", relaxation of the preheated air.
• 6. During the subsequent raising of the piston 25, reducing the volume of the chamber 29, the rotor has passed from its position illustrated in FIG. 11 to that illustrated in FIG. 12, and while the inlet 45 of the combustion chamber 44 passes in front of the opening 36, the expanded hot air contained in the variable-volume chamber 29 is compressed in the combustion chamber 44. This compressed hot air entering the combustion chamber receives an adequate dose of fuel from the injector 39. The pressure and the temperature prevailing in this combustion chamber cause the mixture to self-ignite and burn. This corresponds to the time "c", combustion. The times of injection and ignition will be determined to give optimum efficiency conditions during the residence time of the hot compressed air in the combustion chamber.

The advantages of this engine are the same as those of the first embodiment of the engine.

The variant illustrated in FIG. 14 relates to an engine of the type of that described with reference to FIGS. 7 to 13, but whose succession of times in a cycle is: e, a, b, c, d, f.

The rotor 30 of this modified engine has an intake passage 49 and an exhaust passage 50 whose outlets opening onto the periphery of the rotor are adjacent. A combustion chamber 51 whose inlet 52 and outlet 53 are adjacent and a preheating chamber 54 whose inlet 55 and outlet 56 are also adjacent. This engine also includes a fuel injector 57 and an ignition device 58.

In this embodiment, the rotor is also driven in rotation by the drive shaft at a speed three times lower.

FIG. 15 illustrates a third embodiment of the engine comprising, as in the first embodiment, two chambers with variable volume in opposition but comprising, as in the second embodiment, pistons with linear displacement and a rotor containing the preheating and combustion chambers.

This engine illustrated in FIG. 15 comprises a body 60 comprising two cylinders 61, 6la of parallel axes in which move pistons 62, 62a connected by a conventional linkage to a drive shaft. These two pistons work in opposition and define with the body two chambers 63, 63a with variable volume.

Each of the chambers 63, 63a is connected to a recess formed in the body 60 by a distribution channel 64, 64a, and the orifices of these channels opening into said recess cooperate with the openings of a rotor 65 rotatably mounted in this recess. This rotor 65 is rotated by a shaft 66 connected by gears to the motor shaft. This rotor turns three times slower than the motor shaft.

The rotor 65 comprises an intake passage 67, an exhaust passage 68, a preheating chamber 69 and a combustion chamber 70 as in the second embodiment of the engine.

The body 60 comprises the intake ducts 71, 7la and exhaust 72, 72a, as well as a fuel injector (not shown) and that possibly an ignition device (not shown).

The operation of this engine is identical to that of the second embodiment of the engine at except that a single rotor feeds two variable volume chambers working in opposition. For each cylinder 61, 6la there are exactly the six operating times 1 to 6 of the second embodiment of the engine, each passage or chamber of the rotor 65 working alternately with the distribution channel 64, 64a of one and the other of the variable volume chambers 63, 63a.

This third embodiment can prove to be particularly advantageous, since it could be applied to conventional engine blocks by simply modifying the cylinder head thereof.

Claims (16)

1. Method for converting thermal energy into mechanical energy using a combustion engine comprising a body provided with an intake duct and an exhaust duct, as well as at least one movable member with respect to this body defining at least one chamber of variable volume, characterized by the fact that it comprises a cycle whose number of times is greater than four and by the fact that at least four of these times consist of: at. compressing the air contained in the variable volume chamber, by reducing the volume thereof, inside a preheating chamber; b. the expansion of the variable volume chamber by the expansion of hot air contained in the preheating chamber; vs. the compression, by reducing the volume of the variable-volume chamber, of the expanded hot air which is there in a combustion chamber into which a fuel is introduced causing the combustion of the mixture thus obtained; d. the expansion of the variable volume chamber by the expansion in it of high temperature and high pressure combustion gases from the combustion chamber. 2. Method according to claim 1, characterized in that the complete cycle comprises six times, the two additional times being: e. the introduction of air, through the suction duct, into the variable volume chamber during an increase in the volume of this variable volume chamber; and f. the expulsion, through the exhaust duct, by reducing the volume of the variable-volume chamber, of the expanded combustion gas contained in this chamber. 3. Method according to claim 2, characterized in that the succession of the different times in the complete cycle is: e, a, d, f, b, c. 4. Method according to claim 3, characterized in that the compressed air contained in the preheating chamber is heated by heat exchange with the combustion gas contained in the combustion chamber. 5. Method according to claim 3, characterized in that the pressure in the preheating chamber is limited to a predetermined value, and in that when the pressure in this preheating chamber exceeds the limit value a part of the air in it. 6. Method according to one of the preceding claims, characterized in that the circulation of fluids in the preheating and combustion chambers is unidirectional. 7. Combustion engine comprising a body inside which moves at least one movable member delimiting at least one chamber whose volume varies as a function of the relative position of this movable member by relation to the body, characterized in that the body comprises an intake duct and an exhaust duct; by the fact that it comprises an air preheating chamber, the inlet and outlet of which are arranged so as to communicate, by means of a distribution member, alternately with the variable volume chamber; and by the fact that it comprises a combustion chamber, the inlet and outlet of which are arranged so as to communicate, via the dispensing member, alternately with the variable volume chamber. 8. Engine according to claim 7, characterized in that the preheating chamber and the combustion chamber are arranged so as to constitute a heat exchanger. 9. Engine according to claim 7 or claim 8, characterized in that the distribution member allows to put the variable volume chamber in connection with the intake ducts, respectively exhaust. 1 ₀ . Engine according to claim 9, characterized in that the preheating and combustion chambers are located in the body of the engine; that the dispensing member is constituted by a ring provided with at least one opening in permanent connection with the variable volume chamber; and by the fact that the movable member is constituted by at least one piston connected to the distribution ring and to a motor shaft. 11. Engine according to claim 9, characterized in that the movable member is constituted by a piston moving linearly in a back and forth movement relative to the body; by the fact that the dispensing member is constituted by at least one opening, made in the body and in permanent connection with the variable volume chamber; and by the fact that the preheating and combustion chambers are located in a rotor rotatably mounted in the body. 12. Motor according to claim 11, characterized in that the rotor and the motor shaft are connected by a kinematic connection introducing a ratio of 1: 3 between these elements. 13. An engine according to claim 11, characterized in that the rotor also includes respectively exhaust intake passages, one end of which cooperates with the opening while the other opens onto the lateral faces of the rotor and cooperates with the body intake and exhaust ducts. 14. Motor according to claim 13, characterized in that a rotor cooperates with two variable volume chambers. 15. Engine according to one of claims 7 to 14, characterized in that it comprises several preheating chambers and several combustion chambers each cooperating with at least one variable volume chamber. 16. Engine according to claim 7, characterized in that the inlet and outlet of each preheating and combustion chamber are offset by 180 ° approximately relative to each other.

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