EP0662697B1 - Method for controlling a bistable electromagnetic actuator and device to carry out such method - Google Patents

Description

The invention relates to a method for controlling an actuator. electromagnetic bistable intended for example for the control of a valve of an internal combustion engine. It relates to also a control device and an actuator specially designed for carrying out this process.

The actuators concerned are of the known type with two stable states respectively obtained by the excitation of the coil of two electromagnets (FIGS. 1 a to 1 c ) in the air gap of which a movable armature is arranged (EP-A-376,716 ).

In known methods, one passes from the first stable state to the second stable state and vice versa by establishing the current of the coil of the second electromagnet a certain time Δ T after the interruption of the current of the coil of the first electromagnet. For the capture of the armature released by the first electromagnet to be carried out in an optimal manner, the time difference Δ T must be suitably chosen. If this time is too short, the energy accumulated by the movable armature can cause rebounds, if it is too large the capture may not take place.

More particularly, in the use for the control of valves of an engine, many disturbing factors can intervene and modify the time difference which would be optimal. This is how the charging current of the coils depends on the condition and temperature of the vehicle battery. The mechanical resistances are also a function of the temperature and in particular of the oil temperature, which introduces large differences between cold start and hot engine. The choice of a constant Δ T therefore leads to faulty operations.

The invention proposes to overcome the above drawbacks in a method for controlling an electromechanical actuator with two stable active positions and one rest position, actuator of the type comprising a movable armature linked to a member to be actuated, for example a valve of a internal combustion, this armature being arranged, in the air gap separating a first and a second electromagnets identical placed opposite, equidistant at rest from two electromagnets thanks to the opposing restoring forces of two identical springs, a process in which the switching of one to the other active position is carried out by controlling the excitation of the second electromagnet when a time ΔT, predetermined for normal operating conditions, has elapsed since the power cut command excitation of the first electromagnet and vice versa.

a)- la commande de l'excitation du deuxième électro-aimant est avancée par rapport au temps ΔT prédéterminé pour un fonctionnement optimal dans les conditions normales;

b)- on coupe le courant d'excitation du deuxième électro-aimant à un moment déterminé par la vitesse de déplacement de l'organe mobile:

c)- on rétablit le courant d'excitation après une durée de coupure fonction décroissante de la vitesse de déplacement de l'organe mobile.

The process according to the invention is characterized by the following stages:

a) - the control of the excitation of the second electromagnet is advanced with respect to the predetermined time ΔT for optimal operation under normal conditions;

b) - the excitation current of the second electromagnet is cut off at a moment determined by the speed of movement of the movable member:

c) - the excitation current is restored after a cut-off time that decreases as a function of the speed of movement of the movable member.

Preferably, the interruption of the excitation current of the second electromagnet is controlled during the passage of the armature movable by a reference position which corresponds advantageously in the rest position of the frame.

According to another important characteristic, the duration of the cut is calculated as a function of the elapsed time T _C - T _P between the instant T _C of the start of the cut and the instant T _P of the normal end of the previous command.

Preferably in this case, the duration ΔT _C of the cutoff is an increasing function of the elapsed time T _c - T _P.

A device for implementing the method according to the invention is of the type comprising an actuator electromechanical, with two stable active positions and one rest position, including the movable armature linked to a member to actuate is arranged in the air gap of two electromagnets identical placed vis-à-vis in a housing and means of switching of the control magnets currents, and characterized in that it includes means for generating and deliver a signal to the switching means during the passage of the movable armature at a predetermined position of its travel.

Preferably, the means for generating and delivering the signal have a position sensor linked to the housing the actuator which can advantageously be arranged, for detect the passage of the movable frame, equidistant from two electromagnets.

• les figures 1a à 1c montrent un actionneur connu dans ses positions stables;
• le graphique de la figure 2a montre la position P de l'armature en fonction du temps;
• les graphiques des figures 2b et 2c montrent les signaux de commande d'un procédé connu pour commander un tel actionneur;
• le graphique de la figure 2d montre l'intensité du courant d'une bobine en fonction du temps;
• les figures 3a et 3b montrent les défauts de capture de l'armature dans le procédé connu;
• la figure 4 est un schéma synoptique d'un dispositif pour la mise en oeuvre de l'invention.
• les figures 5a à 5e sont des diagrammes montrant le fonctionnement du procédé conforme à l'invention;
• la figure 6 montre en coupe axiale un actionneur conforme à l'invention appliqué à la commande d'une soupape.

The invention will be better understood in the detailed description which follows and refers to the appended drawings given solely by way of example, and in which:

• Figures 1 a to 1 c show an actuator known in its stable positions;
• the graph in FIG. 2 a shows the position P of the armature as a function of time;
• the graphs of FIGS. 2 b and 2 c show the control signals of a known method for controlling such an actuator;
• the graph in FIG. 2 d shows the intensity of the current of a coil as a function of time;
• Figures 3 a and 3 b show the capture defects of the armature in the known method;
• Figure 4 is a block diagram of a device for implementing the invention.
• Figures 5 a to 5 e are diagrams showing the operation of the method according to the invention;
• Figure 6 shows in axial section an actuator according to the invention applied to the control of a valve.

A known electromechanical actuator with two stable positions and a rest position is shown in FIGS. 1 a , 1 b and 1 c and designated by the general reference 1.

It comprises, fixed in a housing 10, two identical electromagnets 11 and 12 each comprising an excitation coil 21,22. A movable frame 3 consisting of a plate made of magnetic sheet is placed in the air gap e comprised between the two electromagnets arranged opposite. Two identical helical springs 31 and 32 are arranged along the axis XX of the actuator on either side of the plate 3 so as to keep it at rest, that is to say when none of the coils is excited, equidistant from the two electromagnets (Figure 1a). The rod 5 disposed axially and fixed to the center of the plate 3 is connected to the member to be controlled, not shown.

Figure 1b shows a first stable position obtained when the coil 21 of the electromagnet 11 is energized while the coil 22 of the electromagnet 12 is not. The armature 3 is in this case bonded to the armature of the electromagnet 11. FIG. 1 c shows the second stable position obtained when the coil 22 is energized while the coil 21 is not. The armature 3 is in this case bonded to the armature of the electromagnet 12.

The method usually used for switching from the first stable position to the second stable position will now be described with reference to FIGS. 2 a to 2 d . The first position of the armature 3 is represented from O to T1 by the ordinate P1 and the second position by the ordinate P2 reached at time T2 . The current control signals in the coils 21 and 22 are designated respectively by A1 and A2 . At state 1 of these signals the corresponding coil is energized. To pass the armature 3 from P1 to P2 , the current of the coil 21 is first cut by passing the sienal A1 from state 1 to state O. A certain time ΔT after this cut-off, the current I of the coil 22 is controlled by passing the signal A2 from state O to state 1 and the charge of the coil 22 changes as shown in FIG. 2 d .

In order for the armature 3 to be captured by the electromagnet 12 in an optimal manner, the time difference ΔT must be suitably chosen to avoid non-sticking of the armature (FIG. 3 a ), if the magnetic energy is insufficient, or rebounds (Figure 3b ), if there is excess energy.

In addition, in the application to the electromagnetic control of the valves of an internal combustion engine, the operating conditions linked to the vehicle cause variations in the inrush current shown in FIG. 2 d , for example during a start-up at cold and / or if the battery charge is not optimal.

We are therefore led to anticipate the transition from state O to state 1 of signal A2 (or of signal A1 ), with respect to the ΔT determined optimally under normal conditions (hot engine, normal battery charge) so as to have enough energy at the time of contact of the armature 3 with the magnetic circuit of the electromagnet 12 (or 11) in all conditions, which leads to the disadvantage of rebounds if the conditions are normal.

According to the invention, the procedure is to remedy these drawbacks in the manner which will be explained below with reference to FIGS. 5 a to 5 e .

In these figures, the origin of the abscissa represents the instant when the coil of the electromagnet corresponding to the stable state previously produced is de-energized by passage of the corresponding control signal from state 1 to state O to l 'instant T _P. The control of the excitation of the other electromagnet is advanced with respect to the predetermined time Δt (FIG. 5 b ) for optimal operation under normal conditions, as already explained, at time T _a (FIG. 5 c ) .

The excitation current of this electromagnet is then cut at an instant T _c determined by the displacement of the movable armature 3, for example during its passage through a point P _R intermediate of its stroke from P1 to P2 (figure 5 a ). The excitation current is then restored after a cut-off duration calculated as a function of the movement of the armature 3, for example as a function of the time elapsed between the cut at T _P and the passage of the armature 3 through the reference position. P _R.

If the bistable actuator used is perfectly symmetrical like that described in FIGS. 1 a to 1 c , the reference position P _R will preferably be chosen equidistant from the two electromagnets and more generally it will correspond to the rest position of the movable frame 3 (Figure 1 a ).

The duration of the cutoff as a function of the speed of movement of the reinforcement 3 is determined experimentally as a function operating characteristics of the member to be controlled.

For example, when ordering an intake valve with a diameter of 32 mm and a mass of 0.14 kg, the valve corresponding to the smaller of the two intake valves of a four-cylinder engine close to 1.9 l , and whose travel of 6.5 millimeters must be covered in a constant time of 5 milliseconds, the instant T _P of the cutoff of signal A1 being taken as origin, the orders of magnitudes can be the following: Normal order ΔT = 0.8 to 1.4 ms Advanced order TA = 0.5 ms Controlled interruption T _c = 3 ms Duration of the interruption ΔT _c = 0.4 ms

In general, to obtain a cut-off duration that decreases as a function of the speed of movement of the movable member, ΔT _C will be an increasing function of T _c - T _P. The magnetic force is thus properly metered to avoid rebounds of the plate 3 while leaving a sufficient margin to compensate for disturbances in the movement of the plate.

In practice we can retain an increasing linear function of the form ΔT vs = (T vs - T P - I nit ) x K where K is a constant such that O < K < 1 and T _P a motor control data.

I nit is the time which elapses between the end of the command of the previously excited coil and the moment when the plate 3 actually takes off from the magnetic circuit of this coil.

We will now describe a device designed for implementing a method according to the invention.
The device (FIG. 4) comprises an actuator 1 of the type described above and further comprising a position sensor 6 capable of emitting an electrical signal when the armature 3 passes to its rest position. A control system 7 receives, in addition to the usual information for example coming from the control electronics of an internal combustion engine whose actuator 1 controls a valve, the signal emitted by the sensor 6 when the armature passes 3.

The system 7 produces the logic signals A1 and A2 controlling the coils 21 and 22 respectively, by means of a power stage 8.

We will now describe a method which can be used by the control system 7 to trigger the dip at time T _C and calculate its duration ΔT _C. To determine the duration T _C - T _P - Init , one could of course use an analogical method but we know that the numerical methods are more precise and more reliable, in particular by using a clock and a down counter. To multiply T _C - T _P - Init by the factor K , it is then advantageous to use two time bases, one to count, the other to count.

The end of command A1 of the previously energized coil must first be identified, for example by carrying out edge detection. The instant T _P thus identified is chosen as the origin. An up-down counter is then initialized to the value Init and then counted down, when the counter reaches zero, up to the time T _C of passage of the plate 3 in front of the detector 6 is counted using a first clock. We thus obtain T _c -T _P - Init at the output of the up-down counter. The start of the dip is simultaneously triggered at time T _c and a countdown is then made with a second clock. The frequency of the two clocks being in the K ratio, we obtain a duration: ΔT vs = (T vs - T P - Init) x K

It is interesting to use the same circuit for the control of two coils by multiplexing the two inputs and the two control outputs A1 and A2 .

According to a preferred embodiment of an actuator according to the invention shown in FIG. 6 on a scale, the sensor 6 is inserted in the outer wall of the housing 10 equidistant from the armatures of the coils 11 and 12. A valve V and its seat S are shown in the intermediate position corresponding to the rest state of the actuator. The valve stem coincides with the rod 5 driven by the movable frame 3. The equilibrium position P1 corresponds to the closed valve and the position P2 when it is fully open.

The springs 31 and 32 are supported respectively, by their opposite end to the plate 3, on the housing 10 and on the engine cylinder head C.

The actuator usually comprises means for adjustment of the closing position of the valve V in support on its seat S. These means may include wedges or washers 102 arranged under the flange 101 of the housing 10 before fixing on cylinder head C by screws such as 103. It also usually comprises means for adjusting the the zero position corresponding to the rest state. These means may consist of a screw 104 cooperating with a corresponding thread of the housing 10 and on which takes support the end of the spring 31 opposite the plate 3. The axial displacement of the support constituted by the screw 104 allows thus to adjust the rest position of the plate 3. After adjustment, screw 104 is blocked by a lock nut 105.

So that the position of the sensor 6 on the housing wall 10 corresponds as exactly as possible to the zero position of the tray 3, the sensor 6 is centered in a bore of a cylindrical spacer 106 which determines the width of the air gap e between the armatures of the electromagnets 11,12, this air gap defining the total stroke of the plate 3 between its two extreme stable positions P1, P2 .

Claims (10)

1. Method for controlling an electromechanical actuator (1) with two stable active positions and a rest position, said actuator being of the type comprising a mobile armature (3) connected to a body to be actuated, for example a valve (V) of an internal combustion engine, this armature being arranged in the air-gap (e) separating a first and a second identical electromagnet (11, 12) placed facing each other, equidistant in the rest position from the two electromagnets through the opposing return forces of two identical springs (31, 32), in which method the switching from one to the other active position is effected by controlling the excitation of the second electromagnet when a predetermined time ΔT for normal operating conditions has elapsed since the command to cut off the excitation current of the first electromagnet and vice versa, characterised in that it comprises the following stages:

   a) the command to excite the second electromagnet is brought forward in relation to the predetermined time ΔT for optimal operation in normal conditions;

   b) the excitation current for the second electromagnet is cut off at a given moment by the speed of displacement of the mobile body (3, 5);

   c) the excitation current is re-established after a cut-off period ΔT_c that is a decreasing function of the speed of displacement of the mobile body.
2. Method according to Claim 1, characterised in that the cutting off of the excitation current for the second electromagnet is controlled by the passage of the mobile armature through a reference position (P_R).
3. Method according to Claim 2, characterised in that the reference position (P_R) corresponds to the rest position of the armature (3).
4. Method according to any one of Claims 1 to 3, characterised in that the duration of the cut-off is calculated as a function of elapsed time T_c - T_P between the moment T_c of the start of the cut-off and the moment T_P of the end of the preceding command.
5. Method according to Claim 4, characterised in that the duration ΔT_c of the cut-off is an increasing function of time T_c - T_P.
6. Device for implementing the method according to Claims 1 to 5, comprising an electromechanical actuator (1) with two stable active positions and a rest position, the mobile armature of which, connected to a body to be actuated (V) is arranged in the air-gap (e) of two identical electromagnets (11, 12) placed facing each other inside a housing (10) and means for switching the control currents of the electromagnets, characterised in that it comprises means (6) for generating and delivering to the switching means a signal when the mobile armature passes into a predetermined position (P_R) on its course.
7. Device according to Claim 6, characterised in that the means for generating and delivering the signal comprise a position sensor (6) connected to the housing of the actuator.
8. Device according to Claim 7, characterised in that the sensor (6) is arranged so as to detect the passage of the mobile armature (3) into a position equidistant from the two electromagnets.
9. Device according to Claim 8, characterised in that the sensor (6) is inserted into the external wall of the housing (10).
10. Device according to Claim 8 or Claim 9, characterised in that the sensor (6) is centred within a cross-piece (106) delimiting the total course of the plate (3) between its two extreme stable positions (P1, P2).

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