EP2756172A1 - System for transmitting movement from at least two cams to at least one valve - Google Patents

Abstract

The invention relates to a system (7) for transmitting movement from at least two cams (5) to at least one valve (2), said system comprising: a first push element (8) configured to be positioned facing a first cam (5), a second push element (9) configured to be positioned facing a second cam (5) having a different profile from that of the first cam,a locking element (15) that can be moved between a position in which it solidly connects the first (8) and second (9) push elements and a position in which the first (8) and second (9) push elements are not solidly connected to one another, and an electromagnetic actuator (30) configured to move the locking member (15) from one position to the other.

Description

 System for transmitting the movement of at least two cams to at least one valve

 The present invention relates to the transmission of the cam movement to one or more valves of an internal combustion engine, in particular a four-stroke internal combustion engine.

 The invention applies in particular, but not exclusively, to valves with two lift states or disconnectable valves. These are for example valves displaced by the transmission of the cam movement without the intermediary of a pawl or a rocker, according to a technique commonly known as "direct attack". The valves are for example but not exclusively intake valves.

 To extend the optimal operating zone of an internal combustion engine, especially when the engine is operating at half load, it is known to deactivate half of the combustion chambers in such a way as to increase the unit load of the combustion chambers remaining activated. . This deactivation of the combustion chambers can be obtained by the neutralization of the intake and exhaust valves of said chambers.

 Other solutions are also known to extend the optimal operating zone of a heat engine, namely to lift the valve in half and / or reduce its spread at low load and low speed, or disconnect only two of the four valves a sixteen-valve cylinder to improve combustion by acting on the aerodynamics of the gases.

 U.S. Patent Nos. 5,878,705 and 6,273,041 disclose a system for transmitting the motion of two cams mounted on a common cam shaft. These cams have different profiles so that their displacement induces different leaflets for the valve. This transmission system implements a locking member which secures or not pushers respectively associated with one of the cams. The locking member is moved by a hydraulic actuation system implementing a hydraulic circuit whose pressure comes from a hydraulic pump actuated by the engine.

This system is however difficult to implement because it requires the use of a hydraulic circuit. In addition to the complexity of developing such a device, the response times of hydraulic actuators are too high to establish effective engine management strategies. Indeed, the response time of a hydraulic actuator depends on the pressure supply of the hydraulic circuit or the temperature and therefore directly the engine speed. The known systems are also not really satisfactory to allow to vary quickly and reproducibly the state of a valve over a range of temperature and wide regime.

 There is a need to benefit from a system for transmitting the movement of at least two cams to at least one valve, which system allows the valve to have two lift states or is disconnected, and overcomes the aforementioned drawbacks.

 The aim of the invention is to meet this need and it achieves this, according to one of its aspects, with the aid of a system for transmitting the movement of at least two cams to at least one valve, the system comprising:

 a first pusher configured to face a first cam,

a second pusher configured to face a second cam, the second cam having a profile different from the profile of the first cam,

 a locking member, movable between a position in which it secures the first and the second pusher and a position in which the first and the second pusher are not integral, and

 an electromagnetic actuator configured to move the locking member from one to the other of said positions.

 For the purposes of the invention, "valve" must be understood broadly, also designating a piston.

 The use of an electromagnetic actuator makes it possible to reduce the response times during the locking operations as well as to eliminate the hydraulic circuit when the system does not have a hydraulic stop or to simplify it when the system uses a hydraulic stop. The integration of the actuator in a support, such as a cylinder head, is facilitated. The electromagnetic actuation is also independent of the oil pressure and the pump. In addition, the electromagnetic actuation can be performed independently of a valve to the other, unlike the hydraulic actuation which is based on a control by the same solenoid valve shared by all or part of the valves.

This actuation is thus not dependent on the temperature and / or the engine speed. The reduction of the response time of the electromagnetic actuator can also make it possible to implement more complex valve control strategies, for example to achieve a rotating disconnection of the engine intake valves, as explained for example in the French patent application filed by the Applicant under the deposit No. 57621.

 The actuator may be exclusively electromagnetic, which means that when the actuator is activated, ie controlled to move the locking member, only the magnetic field generated by the actuator causes the displacement of the locking member, unlike by example actuators implementing an electromagnetically actuated valve to selectively allow a passage of a liquid moving the locking member.

 The actuation system is driven in particular by the cams directly, that is to say by a contact of at least one of the cams with the transmission system without intermediate tipper, which is not the case when a pawl or rocker arm is used to transmit the movement of the cam.

 The first and the second pusher can be received in a support, in particular the cylinder head of the motor, in a manner that is mobile in translation along an axis. This displacement allows, if necessary, the transmission of the movement of the cam to the valve. The axis of the movement of the pushers is for example the axis in which the valve moves.

 The first and second pushers can be received in the support with indexing, to prevent their displacement in rotation about the axis in which they can move in translation. Such indexing may furthermore make it possible to prevent a rotation movement of the pushers relative to the actuator. The indexing of the first pusher in the support can be performed by the electromagnetic actuator.

 The locking member may comprise at least one locking piece, a first housing being formed in the first pusher, a second housing being formed in the second pusher and the locking piece being configured to be received at least partly in the one and / or the other of the first and second dwellings. When the locking piece is received only in the first or second housing, the first and second pusher are not integral and can move freely relative to each other. When the locking piece is simultaneously received partly in the first housing and partly in the second housing, the first pusher and the second pusher are integral, so that they undergo the same movement. The first housing can be stationary relative to the first pusher. The second housing can be stationary relative to the second pusher.

The locking piece may have an elongate shape along a longitudinal axis. This locking piece has for example a circular or polygonal cross section, in particular rectangular or square. When received in a housing, the longitudinal axis of the locking piece coincides with the axis of the housing.

 The electromagnetic actuator may comprise a body and at least one pin. The pin can be immersed in the magnetic field generated by the electromagnetic actuator and move by translation, in particular under the effect of a modification of this magnetic field, to impose this translation to all or part of the locking member. The pin is for example configured to move only by translation in the body to move all or part of the locking member.

 The locking member may comprise only one locking piece and the electromagnetic actuator may comprise only one pin. The locking piece may be associated with a return member holding it in place in the first housing to prevent it from extending to the second housing. The locking piece may have a portion permanently disposed in the first housing, the pin causing the displacement of the locking piece so that another portion thereof comes into the second housing.

 Alternatively, the locking member may comprise a plurality of locking pieces and the electromagnetic actuator may comprise only one pin. The displacement of the pin can then cause the displacement of one of the locking pieces and the displacement of this locking piece can cause the displacement of the other locking piece (s). One of the locking pieces is for example held by a return member in the first housing while the other locking piece is held in the second housing by another return member and the locking piece of the second housing is moved by the pin through the locking part of the first housing.

 In another variant, the locking member may comprise two locking pieces and the electromagnetic actuator may comprise two pins, each pin interacting with a locking piece, if necessary via an intermediate pin, to secure or not the two pushers. The control of the two pins can be synchronized. In such a case, the actuator is for example configured so that the two pins move in the same direction and different directions.

More generally, each locking piece of the locking member can be associated in a housing with a return member holding it in place in the housing and preventing it from extending simultaneously partly in the first pusher and partly in the second pusher. It is the electromagnetic actuator that causes the movement of the locking piece (s) against the return member (s). At the end of the movement of the locking member (s) by the electromagnetic actuator, the at least one locking piece may be arranged simultaneously in a housing of the first pusher and partly in a housing of the second pusher.

 The pin or pins may be made of any material, for example a ferromagnetic material.

 The pin or pins may be made of a material other than the material used for the locking part or parts. The pin or pins are for example made of a ferromagnetic steel while the one or more locking pieces are made of a hard steel, such as 100C6 steel. The material of the locking piece or parts advantageously allows a good recovery of forces while the material of the pin or pins allows their displacement by the force related to the magnetic field generated by the electromagnetic actuator.

 The magnetic field is generated by the electromagnetic actuator for example using one or more current-carrying coils, also called electromagnets, or permanent magnets whose field can be selectively canceled to move from a position to the other.

 The displacement of the locking piece or pieces can be done when the force exerted by a pin is greater than that exerted by the return member holding the locking piece in the housing.

 The actuator is for example a linear actuator, that is to say it causes a displacement in translation of the locking part or parts. The pin can move in translation to achieve this result. The position of a locking piece will now be referred to as the "rest position" when no magnetic field is exerted by the actuator to move the locking piece. The rest position of the locking piece or pieces may correspond to a position in which each locking piece extends in only one housing, in which case the first pusher and the second pusher are not integral.

As a variant, the rest position of the locking piece or pieces may correspond to a position in which each locking piece extends simultaneously in part in two different housings, in which case the first pusher and the second pusher are solidarity.

 In another variant, the electromagnetic actuator can be bistable, having two rest positions respectively corresponding to a position in which the two pushers are secured and to a position in which the two pushers are not secured, which makes it possible not to have need to generate a magnetic field, in particular by injecting an electric current, to maintain the actuator in one or other of these positions.

 The second pusher comprises for example a bearing portion on the valve to move it against the force of one or more return elements. In such a case, when the first and second pushers are not secured, the movement of the first pusher is not transmitted to the valve and only a displacement of the second pusher can move the valve. Still in this case, when the first and second buttons are secured, the movement of the first pusher can be transmitted to the valve via the support portion of the second pusher.

 A locking piece is for example maintained only in the second housing by a spring disposed in the second housing and the electromagnetic actuator generates to move the locking piece to a first housing a magnetic field to apply on the pin a force of opposite direction , of the same direction, and amplitude greater than that created by the spring. The force applied to the pin and related to the magnetic field can also compensate for frictional forces or vibrational forces that oppose the movement of the locking piece to the first housing when received in the second housing .

 The transmission system is for example configured to transmit to the valve a force displacing it in one direction and the restoring force exerted on the locking piece and the force related to the magnetic field of the actuator have transverse directions, in particular perpendicular directions, to the direction of movement of the valve.

 The system may include a protrusion extending parallel to the direction of movement of the pushers.

 The protrusion is for example integrated with an intermediate pin interposed between the locking piece and the pin when the locking piece is moved by the pin. The displacement of the locking piece by the pin can be done with contact, possibly via the intermediate pin.

According to a first example of implementation of the invention, the intermediate pin is integral with the pin and the locking piece moves relative to the electromagnetic actuator when the first pusher is moved. If necessary, the pin and the intermediate pin can form a single piece.

 The intermediate pin may have a contact surface with the locking piece dimensioned to hold the locking piece in the position in which it secures the first and second pusher when the pin and the locking piece are not at the same height in the support. The contact surface between the pin and the locking piece is thus increased.

 According to this first example of implementation of the invention, the surface of the intermediate pin coming into contact with a surface of the locking piece has a dimension measured parallel to the direction of movement of the first upper pusher, in particular equal to at least once and half or even at least twice, the dimension measured parallel to said direction of said surface of the locking piece.

 According to a second example of implementation of the invention, the intermediate pin is secured to the locking piece and movable relative to the electromagnetic actuator when the first pusher is moved. If necessary, the intermediate pin and the locking piece can form a single piece, in which case the intermediate pin corresponds to an outgrowth of the locking piece.

 The intermediate pin may have a contact surface with the cotter pin sized to hold the locking piece in the position in which it secures the first and second pusher when the pin and the locking piece are not at the same height in the support. The contact surface between the pin and the locking piece is thus increased. According to this second example of implementation of the invention, the surface of the intermediate pin coming into contact with a surface of the pin has a dimension measured parallel to the direction of movement of the first upper pusher, in particular equal to at least once and half, or even at least twice, the dimension measured parallel to said direction of said surface of the pin.

In the above two examples of implementation of the invention, the electromagnetic actuator may comprise a fixed body, for example being integrated into the support, in particular to the cylinder head of the engine. The displacement of the first pusher then corresponds for example to the displacement of the first pusher relative to the body of the actuator. The pin can be configured to move only by translation in the body of the actuator, in order to move the locking piece. The increase of the contact area between the pin and the locking piece can be obtained other than by interposition of an intermediate pin. The protrusion may for example be integrated with the pin or the locking piece. The dimensioning of the surface of the pin, respectively of the locking piece, relative to the surface of the locking piece, respectively of the pin, with which it comes into contact may be as mentioned when using a pin intermediate interposed between the pin and the locking piece.

 In other exemplary embodiments of the invention, neither the locking piece, the pin, nor any other element of the system has a protrusion as described above. Indeed, the forces acting on the pushers and the locking piece or parts when the valve moves may be sufficient to maintain the locking piece or parts in the position in which the first and second push are secured or not secured.

 In all the above examples, the electromagnetic actuator may be of the "pull" type, that is to say that the pin translates from the outside towards the inside of the actuator when a magnetic field is generated. for example, when a current flows through the electromagnet.

 In a variant, in all the above examples, the electromagnetic actuator may be of the "push" type, that is to say that the pin translates from the inside to the outside of the actuator when a field Magnetic flux is generated, for example when a current flows through the electromagnet.

In all the above examples, the one or more of the locking pieces may have a portion permanently disposed outside the structure formed by the first pusher and the second pusher, that is to say that whatever its position in the housing of the first pusher, this locking piece has a portion which extends outside the structure formed by the first and the second pusher, this portion extending towards the electromagnetic actuator. Said portion then protrudes beyond a longitudinal end of the first housing towards the electromagnetic actuator. In this case, a clearance can be provided in the support to allow the passage of said portion during the displacement in translation of the first pusher. When the locking piece carries the above-mentioned protrusion, this protrusion may remain outside the first pusher, being for example received in the clearance formed in the support.

 Alternatively, in all the above examples, the one or one of the locking pieces may be permanently arranged in the structure formed by the first and the second pusher, that is to say that whatever its position in the housing of the first pusher, this locking piece remains contained within the structure formed by the first and second pusher and never protrudes outside the first housing to the outside of said structure. The size induced by the locking piece can then be reduced. When the locking piece carries the protrusion mentioned above, this protrusion may remain inside the structure formed by the first and the second pusher, for example being received in a recess formed in the first pusher, the disengagement being especially formed above an end of the first housing, said end of the first housing opening outwardly of the structure formed by the first and the second pusher to the electromagnetic actuator.

 As a further variant, in all the above examples, the locking piece can protrude outside the first housing of the first pusher towards the outside of the structure formed by the first and the second pusher for some of its positions in the first housing and be contained within said structure for other of its positions in the first housing.

 When the one or the locking pieces is permanently contained in the structure formed by the first and the second pusher, the pin may comprise an end portion permanently extending in the first pusher. When the pin and the first housing are at the same height in the support, the end portion of the pin is received in the first housing and when the pin and the first housing are not at the same height in the support, the portion end is received in a clearance in the first pusher. Such an end portion of the pin in the first pusher may allow angular indexing of the first pusher relative to the electromagnetic actuator, so that when the first housing and the pin are at the same height in the support, first housing and pin are aligned.

Alternatively, in all the above examples, the pin may be out of the first pusher, either permanently, especially when an intermediate pin is used, or only when it is retracted into the body of the electromagnetic actuator. Other means can then be used to index in rotation the first pusher with respect to the electromagnetic actuator. The second pusher may be disposed in a housing formed inside the first pusher, in particular in a central region of the first pusher. In such an example, the first pusher may have two parts separated by the second pusher, each of these parts of the first pusher facing a first cam and having a first housing.

 The first cams can have the same profile and surround the second cam on the camshaft.

 The camshaft has for example an axis perpendicular to the direction of movement of the valve.

 The invention further relates, in another of its aspects, to a device for transmitting the cam movement to at least one valve, the device comprising:

 a transmission system as defined above,

 at least one first cam coming opposite the first pusher, and

a second cam coming opposite the second pusher,

the first cam having a profile different from the profile of the second cam.

 The profile of the first cam and the profile of the second cam may be such that the movement of the first cam induces a displacement of the first pusher in a greater stroke than the stroke of the displacement of the second pusher induced by the movement of the second cam. In such a case, each cam comes into contact with a pusher. When the movement of the first cam is transmitted to the valve, the latter is then in the full lift state and when the movement of the second cam is transmitted to the valve, the latter is in the intermediate lift state.

 Alternatively, the profile of the second cam is a circle, so that the movement of the second cam causes no movement of the second pusher. When the movement of the first cam is not transmitted to the valve, it is disconnected.

 Another aspect of the invention is, according to another of its aspects, an assembly comprising:

 a device as defined above and,

 at least one valve.

The first cam and the second cam can have a profile such that: - When the first pusher and the second pusher are integral, the movement of the first cam is transmitted to the valve so that the valve has a full lift state and,

 - When the first and the second pusher are not secured, the movement of the second cam is transmitted to the valve so that it has an intermediate lift state.

 The assembly thus makes it possible to obtain a valve with two lift states.

 In a variant, the first and second cam may have a profile such that:

 when the first pusher and the second pusher are integral, the movement of the first cam is transmitted to the valve and the latter is displaced, and

- When the first and second pusher are not secured, the movement of the second cam is not transmitted to the valve and the latter remains stationary.

 The assembly then makes it possible to have a valve that can be disconnected.

 In all the foregoing, the first pusher may be mounted on a spring whose axis is parallel to the direction of movement of this pusher, the direction of movement of the pusher preferably being the direction of movement of the valve and, when the first and second pusher are not integral, the movement of the first cam causes a displacement of the first pusher which is absorbed by the spring which then compresses.

 The invention will be better understood on reading the following description of non-limiting examples of implementation thereof and on examining the appended drawing in which,

 FIG. 1 schematically and partially shows an assembly comprising a transmission system according to a first exemplary implementation of the invention,

 FIG. 2 schematically and partially shows an assembly comprising a transmission system according to a second exemplary implementation of the invention and

FIG. 3 schematically and partially shows a transmission system according to a variant of the first exemplary implementation of FIG. 1.

FIG. 1 shows a set 1 according to a first example of implementation of the invention. This set 1 comprises a valve 2 not shown in FIG. 1, but which can be seen from the actuating rod in FIG. 2 and a device 3 transmitting the cam movement to the valve 2. The device 3 comprises cams 5 visible on the Figure 2 and a system 7 transmitting the movement of one or more of the cams 5 to the valve 2. The system 7 is still commonly referred to as "cam follower".

 The assembly 1 is for example disposed inside a support which can be the cylinder head of an engine, the latter being in particular an internal combustion engine.

 The system 7 comprises in the example considered a first pusher 8 and a second pusher 9. The first pusher 8 can be indexed in rotation in the cylinder head of the engine.

 The first pusher 8 and the second pusher 9 are movable in a direction parallel to a longitudinal axis X of the system 7 which, in the example described, corresponds to the direction of movement of the valve 2. The movement of the first pusher 8 in the direction of a fixed structure 6 is made by compressing a spring 14 interposed between the fixed structure 6 and the first pusher 8. This spring 14 is configured to exert a force whose direction is that of the X axis.

 In the example considered, the second pusher 9 is disposed in a housing formed in a central zone of the first pusher 8. The first pusher 8 has for example a cylindrical shape with a circular cross section and extends around the second pusher 9 In a sectional view along a plane containing the X axis, the second pusher 9 is thus surrounded by two parts of the first pusher 8.

 The second pusher 9 comprises a bearing portion 10 through which the pusher or, if appropriate, the first pusher 8 moves the valve 2, as will be seen later.

 As can be seen in FIG. 1, a housing 12 is formed in each part of the first pusher 8 and a housing 13 is formed in the second pusher 9. These housings are for example directed perpendicular to the X axis of the system 7, along a longitudinal axis Y. Depending on the relative position of the first pusher 8 relative to the second pusher 9, the housing 12 and 13 may be at the same height in the cylinder head.

 One or more locking pieces 15 are provided for sliding in the housings 12 and 13. In the example of Figure 1, two locking pieces 15 are provided. These locking pieces may or may not be of the same size, since they can both slide each at a time in a housing 12 or 13.

In the example of Figure 1, one of the locking parts 15 is received in the housing 12 formed in one part of the first pusher 8 while the other locking part is received in the housing 13 formed in the second pusher 9 The housing 12 formed in the other part of the first pusher 8 is here empty and has a hole 17 allowing the escape of the air which is compressed during the movement of the pieces of lock 15, as explained next.

 In the variant shown in Figure 3, the housing 12 formed in the other part of the first pusher 8 receives a solid stop 18.

 The locking pieces 15 may have a dimension, along the Y axis of the housing 12 or 13 in which they are arranged, less than or equal to the length of this housing 12 or 13. Each locking piece may be subjected to restoring force exerted by a corresponding spring 20, this restoring force being configured to prevent the locking piece 15 disposed in a housing 12 from coming into the housing 13 and the one disposed in the housing 13 not to come into the housing 12 which is empty.

 As represented in FIG. 1, the spring 20 mounted in the housing 13 of the second pusher has, for example, an end mounted on a recess 22 formed in the wall of the second housing 13 while its other end is fixed to a collar 24 of the part. lock 15 received in this second housing 12.

 The spring 20 associated with the part of the first pusher 8 can be arranged of the same kind or differently than that mounted in the housing 13.

 In the example of FIG. 1, the locking piece 15 received in the part of the first pusher 8 is fixed, for example by gluing, welding, threading, or the like to an intermediate pin 23 at its end opposite the housing 13. This intermediate pin 23 has a dimension measured parallel to the X axis greater than the corresponding dimension of the locking piece 15 to which it is fixed. The intermediate pin is for example of the same material or material other than the locking piece 15.

 This intermediate pin 23 comes opposite a pin 26 of an electromagnetic actuator 30 which will now be described. The electromagnetic actuator 30 is shown very schematically in Figure 1. It comprises a body 31 having a source intermittently generating a magnetic field. This source may comprise one or more permanent magnets whose field may be canceled intermittently or one or more coils that may or may not be electrically powered to form an electromagnet.

In the example considered, the electromagnetic actuator 30 is of the "push" type. The magnetic field source of the actuator 30 is configured to exert a magnetic field displacing the pin 26 between a position in which it extends wholly or partly inside the body 31 and a position in which it extends in whole or in part out In the example described, the displacement of the pin 26 is in a direction perpendicular to the axis X and parallel to the axis Y of the housing.

 The displacement of the pin 26 allows it to come to contact the intermediate pin 23 and the latter can, when the pin 26 and the locking piece 15 are at the same height and aligned, exert a force on the locking piece 15 to move it.

 In the example considered, the intermediate pin 23 has a surface 33 coming into contact with a surface 34 of the pin 26. As can be seen in FIG. 1, the surface 33 may have, parallel to the X axis, a dimension greater than the corresponding dimension of the surface 34. This dimension of the surface 33 of the intermediate pin 23 relative to the corresponding dimension of the surface 34 of the pin 26 can allow the locking piece 15 to be held in the housing 12 when the pin 26 and the locking piece 15 are not at the same height in the cylinder head. The intermediate pin 23 can indeed then be itself held in place by the pin 26.

 The electromagnetic actuator 30 and / or the spring 20 in the housing 12 can be configured so that the displacement of the pin 26 and its support on the intermediate pin 23 causes the displacement of the locking piece 15 until the latter extend simultaneously partly in the housing 12 of a portion of the first pusher 8 and partly in the housing 13 of the second pusher.

 When several locking pieces 15 are used and are arranged successively along the Y axis, the coming into the second housing 13 of the locking piece 15 which was previously in a housing 12 causes the movement of the other piece previously locked in the housing 13. This locking piece 15 is then partly in the housing 13 and partly in the housing 12 which was previously empty. The compressed air due to these displacements is discharged through the hole 17.

 The displacement of the pin 26 thus causes the pushers 8 and 9 to be secured by the one or more locking pieces 15 extending astride two housings 12 and 13.

 Each portion of the first pusher 8 comes for example opposite a cam 5 having a first profile and the second pusher 9 comes opposite a cam 5 having a second profile different from the first, the second profile cam being disposed on the camshaft 4 between the two cams of first profile.

In the example described, the rest position of the system corresponds to the case where the first pusher 8 and the second pusher 9 are not integral. In this case, the actuator electromagnetic is not activated, that is to say that no locking piece 15 is moved by the pin 26. The movement of the cams 5 of the first profile is transmitted to the first pusher 8 but the displacement of this first pusher 8 induces no movement of the bearing portion 10 of the second pusher 9 and therefore does not move the valve 2. The displacement of the first pusher 8 causes a compression of the spring 14.

 When the cam 5 facing the second pusher 9 has a rounded profile, this cam does not come into contact with the second pusher 9, so that the valve is disconnected since it undergoes no displacement. It remains for example in closed position.

 When the cam 5 opposite the second pusher 9 has a profile allowing the contact of this cam and the second pusher 9, its profile causes a displacement of the valve 2 lower than that which would cause the cam 5 next to each part of the first pusher 8. This is called a valve having an intermediate lift state.

 When the electromagnetic actuator 30 is activated, the one or more locking pieces 15 secure the first pusher 8 and the second pusher 9. Consequently, the first pusher 8 and the second pusher 9, including the bearing portion 10, undergo a same displacement along the axis X induced by the cam 5 opposite each part of the first pusher 8, and this displacement of the bearing portion 10 is transmitted to the valve. According to the profile of the cam 5 facing the second pusher 9, it will speak in this state of activated valve or valve in a full lift state.

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

 In an example not shown, the intermediate pin 23 may be integral with the pin 26 and not the locking piece 15.

 A set 1 according to another embodiment of the invention will now be described with reference to FIG.

 This example differs essentially from that described with reference to Figure 1 in that each housing 12 of the first pusher 8 receives a locking piece 15 and the housing 13 of the second pusher 9 does not receive. In the example of FIG. 2, the housing 13 of the second pusher 9 is closed, for example at mid-length, by a partition 40 supporting on each side an end of a spring 20. The other end of each spring 20 is fixed to one of the locking pieces 15. These springs 20 are configured to exert on each locking piece 15 a force maintaining it in its housing 12 and preventing it from occupying part of the housing 13 of the second pusher 9.

In this example, the electromagnetic actuator 30 is in two parts and each part comprises a body 31, a magnetic field source and a pin 26. Each part of the electromagnetic actuator 30 can interact with a locking piece 15 to move it to a position in which it partially extends into a housing 12 of the first pusher 8 and partly in the housing 13 of the second pusher. This interaction may or may not be performed via an intermediate pin 23 as described above.

 The electromagnetic actuator then comprises a not shown control unit for synchronizing or not the movement of the pins 26.

 When the pushers 8 and 9 are secured, the movement of the cam 5 facing the first pusher 8 is transmitted to the valve 2 while when the pushers 8 and 9 are disconnected, only the movement of the cam 5 opposite the second pusher can possibly be transmitted to the valve 2.

 The invention is not limited to the examples which have just been described.

 The invention may for example apply with a different number of cams.

 The invention can for example be applied for exhaust valves.

 In examples not shown, the system 7 of Figure 1 is devoid of intermediate pin and the displacement of the locking member 15 in the first housing 12 by the electromagnetic actuator 30 is by direct contact between the pin 26 and this piece 15. One of the locking pieces 15 may be integrally contained in the first housing 12, being devoid of a portion protruding out of the housing 12 outward towards the electromagnetic actuator 30.

 The actuator 30 may be of "pull" type, that is to say that in the absence of a generated magnetic field and when the pin is subjected only to the action of a spring disposed in the 31 of the actuator and holding the pin in its rest position, this pin extends outside the body 31, while, when the magnetic field is generated, the pin 26 is moved to the inside of the body 31 of the actuator 30.

 The pin 26 may have an end portion permanently extending into the first pusher 8, this end portion being received in the first housing 12 when the latter and the pin 26 are at the same height in the yoke. A clearance can be provided above the end of the first housing 12 opening towards the electromagnetic actuator 30 to receive the end portion of the pin 26, when the pin 26 and the first housing 12 are not at the same height .

In other examples not shown, an outgrowth extends parallel to the axis X and this protrusion is part of the locking piece 15 disposed in the first housing 12. This protrusion is received in a clearance formed in the first pusher 8 above the first housing 12. The protrusion can thus remain always inside the first pusher 8.

 In other examples not shown, the locking piece 15 disposed in the first housing 12 has a portion extending out of the structure formed by the first 8 and the second 9 pushers. This portion of the locking piece 15 can protrude from the first housing 12 to the pin 26. A clearance can then be formed in the yoke to receive this portion of the locking piece 15 when moving along the X axis of the first 12. This release can then be interposed between the body 31 of the electromagnetic actuator 30 and the first pusher 12.

 In other examples not shown, the locking piece 15 received in the first housing 12 has a portion extending out of the structure formed by the first pusher 8 and the second pusher, as mentioned above, and this portion includes an outgrowth. The protrusion is then also received in the clearance formed in the yoke and receiving said portion of the locking piece when the first pusher 12 moves along the X axis.

 The expression "comprising a" shall be understood as meaning "containing at least one", except when the opposite is specified.

Claims

claims

A system (7) for transmitting the movement of at least two cams (5) to at least one valve (2), the system comprising:

 a first pusher (8) configured to face a first cam (5), a second pusher (9) configured to face a second cam (5), the second cam having a profile different from the the first cam,

 a locking member (15) movable between a position in which it secures the first (8) and the second pusher (9) and a position in which the first (8) and the second (9) pusher are not integral, and

 an electromagnetic actuator (30) configured to move the locking member (15) from one to the other of said positions,

the locking member comprising at least one locking piece (15), a first housing (12) being formed in the first pusher (8), a second housing (13) being formed in the second pusher (9) and the piece locking device (15) being configured to be received at least partly in one and / or the other of the first (12) and second (13) housings, and

the electromagnetic actuator (30) comprising a body and at least one pin (26) immersed in the magnetic field generated by the electromagnetic actuator (30), the pin (26) moving by translation to impose this translation to all or part of the locking member (15).

 2. System according to claim 1, the first and second pusher being movable in a common direction (X) and the system having an outgrowth extending parallel to said direction of displacement (X).

 3. System according to claim 2, comprising an intermediate pin (23) bearing the protrusion, said intermediate pin (23) being interposed between the locking piece (15) and the pin (26) when the locking piece (15). is moved by the pin (26).

 4. System according to claim 3, the intermediate pin (23) being integral with the locking piece (15) and being movable relative to the actuator

electromagnetic (30) when the first pusher (8) is moved, the pin intermediate member (23) having a contact surface (33) with the pin (26) having a dimension measured parallel to the direction of movement of the first upper pusher (8), in particular at least once and half or even twice, the dimension measured parallel to said direction of movement of said surface (34) of the pin (26).

 5. System according to claim 4, the second pusher (9) being arranged in a

 housing formed inside the first pusher (8).

 6. System according to claim 5, the locking member having two locking pieces (15) and the actuator (30) having two pins (26), each pin (26) interacting with a locking piece (15) for secure or not the first (8) and second (9) pusher.

 7. Device (3) for transmitting the cam movement (5) to at least one valve (2), the device comprising:

 a transmission system (7) according to any one of the claims

 preceding,

 at least one first cam (5) facing the first pusher (8), and a second cam (5) facing the second pusher (9),

the first cam having a profile different from the profile of the second cam.

 8. Device according to claim 7, the profile of the first cam and the profile of the

 second cam being such that the movement of the first cam induces a displacement of the first pusher (8) in a greater stroke than the travel of the second pusher (9) induced by the movement of the second cam.

9. Device according to claim 7, the profile of the second cam being circular, so that the movement of the second cam causes no movement of the second pusher (9).

 10. Assembly (1), comprising:

 a device (7) according to any one of claims 7 to 9 and,

 at least one valve (2).

11. The assembly of claim 10, the first cam and the second cam having a profile such that: when the first pusher (8) and the second pusher (9) are integral, the movement of the first cam is transmitted to the valve (2) and the latter has a full lift, and,

 when the first (8) and the second (9) pusher are not integral, the movement of the second cam is transmitted to the valve (2) and the latter has an intermediate lift.

 12. The assembly of claim 10, the first and the second cam having a profile such that:

 when the first pusher (8) and the second pusher (9) are integral, the movement of the first cam is transmitted to the valve and the latter is displaced, and when the first (8) and second (9) pusher are not integral, the movement of the second cam is not transmitted to the valve (2) and it remains stationary.