WO2013038087A1

WO2013038087A1 - System for transmitting movement from a cam to at least one valve

Info

Publication number: WO2013038087A1
Application number: PCT/FR2012/051942
Authority: WO
Inventors: Nicolas Gelez; Julien Hobraiche; Gabriel KOPP; Benoît MAURICE
Original assignee: Valeo Systemes De Controle Moteur
Priority date: 2011-09-12
Filing date: 2012-08-28
Publication date: 2013-03-21
Also published as: FR2979944A1; FR2979944B1; EP2756173A1

Abstract

The invention relates to a system for transmitting movement from a cam (15) to at least one valve, said system comprising: a push element (21) configured to be positioned facing the cam (15), said push element including a passage (30) in which an actuation stem (8) of the valve (3) can slide and comprising a housing (27) through which the passage (30) extends; a locking part (28) disposed in the housing (27), said part having a through-hole; and an electromagnetic actuator (50) configured to move the locking part (28) in the housing (27) so that it is/is not occupying a position in which the through-hole forms part of the passage (30).

Description

System for transmitting the movement of a cam to at least one valve

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

The invention applies in particular but not exclusively to disconnectable valves. These are for example valves displaced by the transmission of the movement of a cam 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.

US Patent 6,401,676 discloses an assembly comprising a cam, a valve and a system for transmitting the movement of the cam to the valve. The transmission system comprises a pusher in which is provided a passage capable of receiving an actuating rod of the valve. A housing is formed in the pusher, this housing being traversed by the passage and a locking piece is disposed in the housing in which it can slide in a direction perpendicular to the direction of movement of the pusher. A through hole is provided in the locking piece and this hole may be aligned with the passage according to the position in the housing of the locking piece. When the hole is aligned with the passage, the movement of the pusher related to the movement of the cam is not transmitted to the valve stem since it slides in the passage in case of displacement of the pusher. When the hole and the passage are not aligned, a portion of the locking piece bears on the actuating rod so that this support transmits the movement of the cam to the valve stem.

US 6,401,676 teaches moving the locking piece in the housing for to transmit or not to the valve the movement of the cam by means of a hydraulic actuator 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 a cam to at least one valve, this system allowing the valve to be disconnected, and overcoming the aforementioned drawbacks.

The object of the invention is to meet this need and it achieves this, according to one of its aspects, by means of a system for transmitting the movement of a cam to at least one valve, comprising:

a pusher configured to face a cam, the pusher comprising a passage through which an actuating rod of the valve can slide, the pusher comprising a housing through which the passage passes,

a locking piece arranged in the housing, said part having a through hole,

- An electromagnetic actuator configured to move the locking piece in the housing so that it occupies or not a position in which the through hole is part of the passage.

The use of electromagnetic locking means makes it possible to reduce the response times during the locking operations as well as to suppress the hydraulic circuit when the system does not include any hydraulic stop. For the case where the system comprises one or more hydraulic stops, the absence of hydraulic actuator makes it possible to significantly simplify the hydraulic circuit. The integration of the electromagnetic actuator into a support, such as a cylinder head, is facilitated. actuation electromagnetic is also independent of the oil pressure and the pump. This actuation is thus not dependent on the temperature and / or the engine speed. The reduction of the response time of the electromagnetic actuator may also make it possible to implement more complex valve control strategies, for example to achieve a rotary disconnection of the engine intake valves, as explained for example in the application French patent application filed by the Applicant under the filing number 10 57621.

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.

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

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

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

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 the housing, the longitudinal axis of the locking piece may coincide with the axis of the housing.

The pusher may be configured to move in translation in one direction to transmit movement of the cam to the valve.

The axis of the housing may be oblique, in particular perpendicular, with respect to the direction in which the pusher moves to transmit or not the movement of the cam to the valve. The housing can be substantially stationary relative to the pusher.

The pusher can be received in the cylinder head of the engine with indexing, in order to prevent its rotational movement in this cylinder head around the direction in which the pusher moves in translation. Such indexing may furthermore make it possible to prevent a displacement in rotation of the pusher with respect to the actuator.

Alternatively, the indexing of the pusher in the cylinder head can be performed by the electromagnetic actuator.

The actuator may include a pin configured to move the locking member into the housing. The actuator may comprise a body fixed in the cylinder head of the engine. The pin is for example movable between a position in which it extends wholly or partly in the body of the actuator and a position in which it extends wholly or partly outside said body.

The pin can be immersed in the magnetic field generated by the actuator and move by translation, in particular under the effect of a modification of this magnetic field, to impose this translation to the locking piece.

The housing can be open at at least one of its longitudinal ends and this opening can allow the passage of the pin to move the locking piece.

The pusher may include a member for holding the locking piece in the housing in a position in which the hole is part of the passage. Upon movement of the pusher, the valve actuating rod slides in the passage which is not obstructed by the locking member, so that the movement of the cam is not transmitted to the valve. The valve is then disconnected.

In a variant, the holding member holds the locking piece in a position in which the hole and the passage are not aligned. During a movement of the pusher, the locking piece which is also moved comes to press the actuating rod of the valve, so that the movement of the cam is transis to the valve which is then connected.

The holding member may comprise a spring and a stop, the spring being configured to exert a force in the direction of the stop. The spring and the stop are for example arranged at opposite ends of the housing and each end of the locking piece is then held in place.

The position provided by the holding member may correspond to the rest position of the locking piece, that is to say to a position in which the electromagnetic actuator does not generate a magnetic field.

The rest position may correspond to the position of the locking piece in the housing to which the valve is connected. The electromagnetic actuator can then moving the locking piece to a position in the housing in which the valve is disconnected.

Alternatively, the rest position may correspond to the position in the housing of the locking piece in which the valve is disconnected. The electromagnetic actuator can then move the locking piece in the housing to a position in which the valve is connected.

In the case where the pusher comprises the above holding member, the movement of the locking piece from its rest position may be to move it away from the stop.

Alternatively, the two above rest positions can coexist, the actuator then being bistable, which makes it unnecessary to generate a magnetic field, in particular by injecting an electric current, to maintain the actuator in the one or the other of these two rest positions.

The actuator is for example a linear actuator, that is to say it causes a displacement in translation of the locking piece. The pin can move in translation to achieve this result.

The displacement in translation of the pusher corresponds to a displacement relative to the body of the electromagnetic actuator and the system may comprise an outgrowth extending parallel to the direction of movement of the pusher.

According to an exemplary implementation of the invention, the protrusion is integral with the locking piece.

According to another example of implementation of the invention, the protrusion is integral with the pin of the actuator.

According to another example of implementation of the invention, the protrusion is carried by an intermediate pin interposed between the pin and the locking piece when the pin moves the locking piece.

In all the exemplary embodiments of the invention above, the surface of the protrusion may come into contact with a surface of the pin or the locking piece and the contact surface of the protrusion may present a dimension, measured parallel to the direction of displacement of the pusher, greater than the dimension, measured parallel to said direction, of the contact surface of the pin or the locking piece, in particular being at least 1.5 greater, or even double.

Such an arrangement of the protrusion may make it possible to increase the contact area between the protuberance and the locking piece or the pin. The surface of the outgrowth may be dimensioned to maintain the locking piece in the position in which the valve is connected or disconnected when the pin and the housing are not at the same height in the cylinder head.

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 exerted on the pusher and the locking piece when the valve is connected may be sufficient to maintain the locking piece in the position allowing the transmission of the movement of the cam to the valve when the pin and the housing do not are not at the same height. Furthermore, in the disconnected position, the presence in the passage of the valve stem keeps the locking piece in position when the housing and the pin are not at the same height in the cylinder head.

The displacement of the locking piece by the electromagnetic actuator can be effected by contact. This is for example a contact between the pin and the locking piece or contact between the pin and the locking piece via the intermediate pin.

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 locking piece can permanently, that is to say whatever its position in the housing of the pusher, have a portion which extends outside the pusher, this portion protruding beyond a longitudinal end of the housing. In this case, a clearance can be provided in the cylinder head to allow the passage of this portion of the locking piece during displacement in translation of the pusher. When the locking piece carries the aforementioned protrusion, this protrusion may remain outside the pusher, being for example received in the clearance formed in the cylinder head.

Alternatively, in all the above examples, the locking piece can permanently, that is to say whatever its position in the housing of the pusher, to be contained inside the pusher, that is to say that it never protrudes outside the housing. The size induced by the locking piece can then be reduced. When the locking piece carries the aforementioned protrusion, the latter may remain inside the pusher, being for example received in a clearance formed in the pusher, the clearance being formed especially above one end of the housing.

As a further variant, in all the above examples, the locking piece may protrude outside the pusher housing for some of its positions in the housing and be contained within the pusher for other of its positions in the housing. housing.

When the locking piece is permanently contained in the housing of the pusher, the pin may comprise an end portion permanently extending in the pusher. When the pin and the housing are at the same height in the yoke, the end portion of the pin is received in the housing and when the pin and the housing are not at the same height in the yoke, the end portion can be received in a clearance in the pusher. Such an end portion in the pusher may allow angular indexing of the pusher relative to the electromagnetic actuator, so that when the housing and the pin are at the same height in the yoke, housing and pin are aligned.

Alternatively, in all the above examples, the pin can be out of the 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 pusher relative to the electromagnetic actuator.

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

- a system as defined above and,

a cam,

the cam and the pusher being configured so that the cam can come to press the pusher.

Depending on the alignment of the hole of the locking piece and the passage in the pusher, the support of the cam on the pusher is transmitted or not to the valve, leading to the displacement thereof between a closed position and a open position.

The cam can be unique. The pusher can be unique. The subject of the invention is, according to another of its aspects, a set comprising:

a device as defined above and,

- A valve, the valve having a rod configured to slide in the passage in the pusher.

The invention will be better understood on reading the following description of a nonlimiting example of implementation thereof and on examining the appended drawing in which:

FIG. 1 schematically represents an assembly according to a first exemplary implementation of the invention,

FIG. 2 is a detail of the assembly of FIG. 1,

FIG. 3 represents a locking piece of the assembly of FIG. 1,

FIG. 4 is a view similar to FIG. 2 of a detail of an assembly according to a second exemplary implementation of the invention and,

FIGS. 5 and 6 are views similar to FIG. 2 of a detail of an assembly according to a third exemplary implementation of the invention, showing respectively the connected valve and the disconnected valve,

FIGS. 7 and 8 are views similar to FIG. 2 of a detail of an assembly according to a fourth example of implementation of the invention, showing respectively the connected valve and the disconnected valve,

FIG. 9 is a view similar to FIG. 2 of a detail of an assembly according to a fifth embodiment of the invention,

FIG. 10 is a view similar to FIG. 2 of a detail of an assembly according to a sixth example of implementation of the invention, and

FIG. 11 is a view similar to FIG. 2 of a detail of an assembly according to a seventh embodiment of the invention.

FIG. 1 shows a set 1 according to a first example of implementation of the invention. This assembly 1 is disposed wholly or partly inside a cylinder head 2.

The assembly 1 comprises a valve 3 and a device 4 configured to move the valve 3. The valve 3 is mounted in a conduit 6 with the possibility of displacement and it closes or not this conduit 6 depending on its position. The duct 6 belongs for example but not limited to the intake circuit of an internal combustion engine. As shown, the valve 3 comprises an actuating rod 8. This rod 8 can slide inside a guide sleeve 9 disposed in the cylinder head 2. The rod 8 is held in a given position by a spring 10 of which one end is fixed to the yoke 2 and whose other end is fixed to a part 11 secured to a portion 12 of the rod 8.

The device 4 comprises a cam 15 mounted on a cam shaft 17 and a system 20 for transmitting the movement of the cam 15 to the valve 3.

An example of such a system 20 will be described with reference to FIG.

The system 20 comprises a pusher 21 whose surface 22 comes opposite the cam 15. The contact between this surface 22 and the cam 15 causes the pusher to move in a direction X parallel to the direction of movement of the rod 8 of the 3. The displacement of the pusher 21 can be effected against the force exerted by a spring 24 interposed between the yoke 2 and a surface of the pusher 21 opposite the surface 22. The springs 10 and 24 can be coaxial, the spring 24 being example mounted around the spring 10, as shown in Figure 2.

The pusher 21 comprises a housing 27 in which a locking piece 28 can move. As shown in FIG. 2, this housing 27 has a longitudinal axis Y transverse to the X direction of displacement of the pusher 21. The Y axis is example perpendicular to the X direction.

As can be seen in Figure 2, a passage 30 is formed in the pusher 21, this passage being adapted to receive the actuating rod 8 of the valve 3 during its

displacement. The end of this passage 30 near the cam 15 is closed by a grain 31 allowing an initial clearance clearance. As can be seen, the passage 30 extends through the housing 27.

The locking piece 28 may be as shown in Figure 3. It is for example elongate along an axis which is parallel to the Y axis when it is received in the housing 27. The locking piece 28 may comprise any shape compatible with its introduction into the housing 27. The locking piece 28 has for example a circular or polygonal cross section, in particular square or rectangular.

At one of its longitudinal ends, a slot 32 whose role will be specified later is provided while a cavity 33 is formed at its other longitudinal end. The locking piece 28 further comprises a through hole 35 formed substantially in its median portion between two lateral faces 36. This hole may have dimensions allowing the actuating rod 8 of the valve to be received in the hole 35.

In all examples of implementation of the invention, the locking piece 28 and the housing 27 may be such that the locking piece 28 can only move in translation in the housing 27 when it is in the latter. During its movement in the housing 27, the locking piece 28 can occupy a position in which the through hole 35 is part of the passage 30.

The housing 27 comprises a holding member in a given position of the locking piece 28. This holding member is for example formed by a spring 40 received at one end of the housing 27 and by a stop rod 41 disposed at another end of the housing 27. As can be seen in Figure 2, the spring 40 is disposed in the cavity 33 of the locking piece 28 and is connected on the one hand to the locking piece 28 and other also in the housing 27. Also in the example described, the stop rod 41 and the slot 32 have complementary shapes.

The locking piece can then be held in a given position by the action of the spring 40 at one of its ends which pushes it towards the stop rod 41 against which it rests at its other end.

This given position, which can also be called "rest position", is for example that in which the through hole 35 is not aligned with the passage 30, unlike the position shown in Figure 2.

The locking piece may comprise a surface 55 adapted to come opposite the upper end of the actuating rod 8 of the valve and this surface 55 may comprise a flat part 56, this flat part ensuring a satisfactory contact with the locking piece. 28 and the actuating rod 8.

When the through hole 35 is not part of the passage 30, the flat part 56 can bear against the upper end of the actuating rod 8. In this configuration, the movement of the cam 15 displaces the surface 22 of the pusher 21 and this displacement is transmitted to the locking piece 28 which, by action of the flat portion 56 on the upper end of the actuating rod 8, causes the displacement, in particular the opening, of the valve 3 which is then connected.

The locking piece 28 and the housing 27 may be made in accordance with the teaching of US Pat. No. 6,401,676, the contents of which are incorporated by reference to the this request with respect to the description of the locking part and the housing made therein.

As can be seen in FIG. 2, the system 20 also comprises an actuator 50 configured to move the locking piece 28 in the housing 27.

The actuator 50 is shown very schematically in Figure 2. It comprises a body 51 having a source intermittently generating a magnetic field. This source may comprise one or more permanent magnets whose field may be annulled by an intermittent electromagnet or one or more coils that may or may not be electrically powered to form an electromagnet. The body 51 is for example fixed to the cylinder head 2.

The electromagnetic actuator further comprises a pin 52 which may be made of a ferromagnetic material. The magnetic field source of the actuator 50 is configured to exert a magnetic field displacing the pin 52 between a position in which it extends wholly or partly inside the body 51 and a position in which it extends. in all or part outside the body 51. In the example described, the displacement of the pin 52 is parallel to the Y axis of the housing.

Still in the example described, the actuator 50 is of the "push" type. A spring 70 not shown in this figure 2 holds the pin 52 in the body 51 of the actuator and, when a magnetic field is generated, the force exerted by the magnetic field on the pin 52 moves it outwards. of the body 51, despite the force of the opposite direction exerted by the spring 70.

The displacement of the pin 52 due to the actuation of the electromagnetic actuator 50 allows it to move the locking piece 28 from the idle position described above. The magnetic field created by the actuator 50 and / or the spring 40 and / or the spring 70 are for example such that the support of the pin 52 against the end of the locking piece 28 bears against the stop rod 42 causes the locking piece to move away from the stopper rod 42 by compressing the spring 40.

The locking piece is then moved to a position shown in Figure 2 in which the through hole 35 is part of the passage 30.

In such a case, when the cam 15 presses on the surface 22 of the pusher 21, the pusher is moved in the direction X but this movement is not transmitted to the valve 3 since the actuating rod 8 slides in the passage 30 , including at the locking piece 28 where it is received in the through hole 35. The valve is then disconnected. The valve 3 then remains in the same position, independently of the movement of the cam 15, for example in the closed position.

As can be seen in FIG. 2, an intermediate pin 58 can be interposed between the locking piece 28 and the pin 52 during the displacement of the locking piece 28 by the pin 52. This intermediate pin 58 is in the example described in solidarity with the locking piece 28, so that it can move relative to the actuator 50 in translation in the X direction.

Intermediate pin 58 includes a protrusion 59 extending along the X direction of movement of pusher 21. Stem 59 may have a surface 60 engaging a surface 61 of the pin and the dimension measured along the X direction of the surface 60 of the protrusion 59 may be greater, being for example equal to twice, the dimension measured along the X direction of the surface 61 of the pin 52. As can be seen, a clearance 62 may be provided in the yoke 2 to allow the displacement of the protrusion 59 when the locking piece 28 which it is secured follows the movement of the pusher 21 in the direction X.

The invention is not limited to such an example. The intermediate pin may alternatively be secured to the pin 52.

In other examples which will be described later, the protrusion is directly integrated with the locking piece 28 or the pin 52, so that there is no element interposed between the pin 52 and the workpiece locking 28 when the latter is moved by the pin 52.

FIG. 4 partially shows an assembly 2 differing from that just described in that it furthermore comprises means for offsetting the pusher 21 with respect to the actuating rod 8, so that it can no longer move in the passage 30.

In the example of Figures 5 and 6, the system 20 is devoid of intermediate pin and the displacement of the locking piece 28 by the electromagnetic actuator 50 is by direct contact between the pin 52 and the locking piece 28. In the example shown, the locking piece 28 is completely contained in the housing 27. In fact, that the valve 3 is connected, as in Figure 5, or that it is disconnected, as in Figure 6, the piece of locking 28 is devoid of protruding portion out of the housing 27 beyond a longitudinal end thereof.

In the example of FIGS. 5 and 6, the actuator 50 is of the "pull" type, that is to say that the absence of a generated magnetic field, as shown in FIG. 5, and when the pin is subjected only to the action of the single spring 70, it extends outside the body 51, whereas when the magnetic field is generated, the pin 52 is moved inwardly of the body 51 of the actuator 50., as can be seen in Figure 6. In the example of Figures 5 and 6, the pin has a portion end 71 extending permanently into the pusher 21, this end portion 71 being received in the housing 27 when the housing 28 and the pin 52 are at the same height in the cylinder head. A clearance 73 is provided above one end of the housing 27 to receive the end portion 71 of the pin 52 when the pin 52 and the housing 27 are not at the same height.

The force exerted by the spring 70 may be greater than that exerted by the spring 40 and maintain the locking piece 28, in the absence of a magnetic field, in abutment in the position shown in FIG. 5 in which it allows the transmission of the movement of the cam 15 to the valve 3.

The force generated by the electromagnetic actuator 50 can hold the locking piece 28 in abutment in the position shown in FIG. 6 in which the stem 8 of the valve 3 can slide in the passage 30 without the movement of the cam 15 is transmitted to the valve 3.

The example of FIGS. 7 and 8, in which the valve 2 is respectively connected and disconnected, differs from the example of FIGS. 5 and 6 only in that the electromagnetic actuator 50 is of the "push" type; that is, in the absence of a generated magnetic field, the pin 52 extends further into the body 51 than when a magnetic field is generated.

In the absence of a generated magnetic field, the spring 40 and the spring 71 exert collinear forces and in the same direction so that the through hole 35 is not aligned with the passage 30, as shown in FIG. the magnetic field is generated, the force that it induces on the pin 52 causes the latter to move towards the outside of the body 51 so that the locking piece 28 occupies in the housing 27 a position in which the hole 35 makes part of the passage 30, as shown in FIG.

The example of FIG. 9 differs from that of FIGS. 5 and 6 only in that an outgrowth 75 extending parallel to the direction of movement of the pusher 21 in the yoke forms part of the locking piece 28. This protrusion 75 is received in a clearance 77 formed in the pusher 21 above the housing 27. The protrusion 75 remains in the example always described inside the pusher 21. Another example differing from that of FIGS. 7 and 8 only in that the locking piece 28 bears a protrusion similar to the protrusion 77 of the locking piece 28 of the example of FIG. 9 is covered by the invention, although not shown.

The example of Figure 10 differs from that of Figures 5 and 6 in that at least when the valve is disconnected, the locking member 28 has a portion 79 extending out of the pusher 21. As can be seen this portion 79 protrudes out of the housing 27 towards the pin 52. A clearance 80 can then be formed in the yoke to receive the portion 79 during the movement in the X direction of the pusher 21. The clearance 80 is interposed between the body 51 the electromagnetic actuator 50 and the pusher 21. The portion 79 may extend out of the pusher 21, whether the valve 3 is connected or not.

An example not different from that shown in Figures 7 and 8 that the presence of the clearance 80 and the portion 79 of the pin which have just been described is also covered by the present application.

Likewise, the example of FIG. 9 can be modified to include the clearance 80 and the portion 79 of the pin, whether the actuator 50 is of the "push" type or of the "pull" type.

The example of FIG. 11 differs from that of FIG. 10 only in that the locking piece 28 has an outgrowth 81 which forms part of the portion 79 projecting out of the housing 27. This outgrowth 81 is then received in the clearance 80 when the pusher 21 moves in the direction X.

Of course, such an outgrowth 81 and such a portion 79 may also be provided in all the examples of FIGS. 7 to 9, including in the case of FIG. 9 with a "push" type actuator.

Claims

claims

1. System (20) for transmitting motion from a cam (15) to at least one

valve (3), comprising:

a pusher (21) configured to face the cam (15), the pusher (21) comprising a passage (30) in which an actuating rod (8) of the valve (3) can slide, the pusher ( 21) having a housing (27) through which the passage (30) passes,

- a locking piece (28) disposed in the housing (27), said part having a through hole (35),

an electromagnetic actuator (50) configured to move the locking piece (28) in the housing (27) to or out of a position in which the through hole (35) is part of the passage (30),

the actuator (50) comprising a pin (52) configured to move the locking piece (28) into the housing (27), the pin (52) being immersed in the magnetic field generated by the actuator (50) and moving by translation to impose this translation to the locking piece (28) in the housing (27).

2. System according to claim 1, the pusher (21) comprising a holding member (40, 41) of the locking piece (28) in the housing (27) in a position in which the hole (35) is not aligned with the passage (40).

3. System according to the preceding claim, the holding member comprising a

spring (40) and a stop (41), the spring (40) being configured to exert a force towards the stop (41).

4. System according to the preceding claim, the electromagnetic actuator (50) being configured to move the locking piece (28) away from the stop (41), so that the hole (35) forms part of the passage (30). .

5. System according to any one of claims 1 to 4, the pusher (21) being movable relative to the electromagnetic actuator (50) in a direction (X) and the system comprising an outgrowth (59) extending in parallel. to said direction

(X) displacement

6. System according to claim 5, the protrusion (59) being secured to the locking piece (28).

7. System according to claim 6, the surface (60) of the protrusion (59) coming into contact with a surface (61) of the pin (52) and the ratio between the dimension measured parallel to the direction (X). displacing the contact surface (60) of the projection (59) and the dimension measured parallel to said direction (X) of the contact surface (61) of the pin (52) being greater than 1, in particular being at least 1.5 or even at least 2.

8. System according to any one of claims 1 to 4, the system being devoid of protrusion extending parallel to the direction (X) of displacement of the pusher (21) relative to the electromagnetic actuator (50).

9. System according to any one of claims 1 to 8, the locking piece (28) having a portion (79) extending continuously outside the pusher (21).

10. System according to any one of claims 1 to 8, the locking piece (21) being permanently contained within the pusher (21).

11. System according to claim 10, the pin (52) having an end portion (71) extending permanently in the pusher (21).

12. Device (4) for moving at least one valve (3), comprising:

a system (20) according to any one of the preceding claims and, a cam (15),

the cam (15) and the pusher (21) being configured so that the cam (15) can come to press the pusher (21).

13. Device according to claim 12, the cam being unique.

14. Together (1), comprising:

a device (4) according to claim 12 or 13 and,

a valve (3), the valve (3) having a rod (8) configured to slide in the passage (30) in the pusher.