IT202000032225A1 - METHOD AND SYSTEM FOR CHECKING THE TIMING OF AT LEAST ONE SUPPLY DISTRIBUTION VALVE FOR INTERNAL COMBUSTION ENGINES - Google Patents

Description

?Method and system for checking the timing of at least one distribution valve for internal combustion engines?

DESCRIPTION

TECHNOLOGICAL BACKGROUND OF THE INVENTION

Field of application.

The present invention relates to a method and system for controlling the timing of at least one fuel distribution valve for internal combustion engines.

In particular, the invention relates to a method and system for controlling the timing of the fuel distribution, in an internal combustion engine, by means of electromagnetic retention of the intake and exhaust valves.

The present invention can also be applied for pressure ratio regulation for internal combustion engines.

Description of the prior art.

? It is well known that internal combustion engines, in particular four-stroke engines, are equipped with intake and exhaust valves which determine, respectively, the introduction into the combustion chamber of the fuel-air mixture and the expulsion of the exhaust gases.

The opening and closing of the intake and exhaust valves are regulated by eccentric elements, typically cams, the profile of which determines the displacement and therefore the opening and closing of the valves.

The opening and closing of the valves is synchronized with the rotation of the crankshaft.

This rotation can be expressed quantitatively by means of an angular measure called crank angle.

The timing of the distribution pu? therefore be expressed as a function of the opening and closing crank angles of the valves with respect to the so-called ?bottom dead centre, PMI? and ?top dead centre, TDC?.

? otherwise? known that these crank angles of opening and closing of the valves with respect to the lower dead centres, PMI, and upper, PMS, are decisive in defining the performance of the engine at the different speeds of rotation as well as? the quantity? of pollutants produced during operation.

For this reason, numerous solutions have been developed (for example, adopted by various car manufacturers) which include variable timing distribution systems in order to optimize the timing according to the conditions of use of the engine and its speed (rpm). of operation.

Among the known timing systems of the distribution, the following can be mentioned for example: phase shifters with angular displacement (VCT<? >Alfa Romeo, VARIOCAM<? >Porsche), phase shifters with pi? valve cams (VALVELEFT<? >Audi, VTEC<? >Honda), tappet shifters (MDS<? >Dodge) and more? recently variable valve timing and lift systems (VALVETRONIC<? >Bmw, MULTIAIR<? >Fiat, VALVEMATIC<? >Toyota).

The systems mentioned above are based on ?sophisticated? controls, by mechanical actions carried out by one or more? cams served by sophisticated motorized mechanisms or by hydraulically actuated transmission parts or by hydraulic actuators that require complex hydraulic systems. Such sophisticated controls result in a certain level of complexity? (for example, they require numerous actuators with high response speed requirements, mechanical parts characterized by high precision machining and therefore characterized by high construction costs), with relatively limited phasing excursions (delays, advances) and in some cases unable to delay closing over large angular intervals.

Despite the variety of the aforementioned systems, therefore remains the? need to provide solutions more? simple, in some respects, and on the other hand more? effective, in terms of optimization of the timing control and with timing excursions (crank angles of advance or delay) more? broad.

In this regard, solutions based on a different approach have recently emerged, which consists in using a different type of actuators, in particular electromagnetic actuators.

Note how the two aforementioned approaches are very different, and in some respects incompatible: in the first case, an improvement in performance is sought through the application of auxiliary mechanisms or auxiliary hydraulic control systems (in fact, more complex and sophisticated) keeping the type of controlled actuators fixed (cams); according to the other approach, the type of actuator is changed.

For example, the so-called ?camless? valve control systems, which use electromagnetic actuators, belong to this second category.

In these systems the valves are integral with a mobile armature of the electromagnet which is attracted (or even repelled if permanent magnets are used) by the fixed core of the opening or closing electromagnet according to the needs. opening/closing and relative timing.

However, even these ?camless? have significant drawbacks.

The main drawback consists in the fact that, in order to be able to open and close the valves rapidly, especially at high engine speeds, electromagnets of high power and also bulky are required. In fact, the magnetic force of attraction (and/or repulsion if permanent magnets are used) between the mobile armature and the fixed core must repeatedly accelerate and decelerate both the mass of the valve and the mass of the mobile armature of the electromagnet.

Another disadvantage you can? locate in the fact that the initial force of attraction ? clearly lower than the maximum attraction force that the electromagnet can? to provide. The reason ? that the displacement of the mobile armature occurs when there is necessarily a distance D (equal to the lift of the valve) between the pole expansion of the mobile armature and the pole expansion of the fixed core measured along the displacement, which greatly reduces the attractive force (and/or repulsive) due to the low permeability? magnetic gap. The maximum force is obtained only when the distance D ? essentially nothing.

A further drawback derives from the fact that such systems must necessarily provide devices capable of decelerating the masses to prevent there being a hammering effect between the pole pieces with consequent wear and limited life times.

In the technical sector considered, ? therefore the need is strongly felt to have methods and systems for controlling the timing of the power supply distribution for internal combustion engines which are capable of providing at least partially improved performance with respect to the aforementioned desired requirements, and in particular which are simple, rapid , not bulky, such as not to require machining of high precision (and therefore relatively cheap) and such as to provide a more? wide excursion in the advance or delay of the opening and/or closing of the valves, and therefore of a phasing more? flexible.

SUMMARY OF THE INVENTION

? The object of the present invention is to provide a method for controlling the timing of at least one fuel distribution valve for internal combustion engines, which makes it possible to at least partially obviate the drawbacks described above with reference to the prior art, and to meet the above-mentioned needs particularly felt in the technical sector considered. That purpose? achieved by a method according to claim 1.

Further embodiments of this method are defined by claims 2-7.

A further object of the present invention ? that of providing a system for controlling the timing of the power supply distribution for internal combustion engines, capable of carrying out the above method. That purpose? achieved by a method according to claim 8.

Further embodiments of this system are defined by claims 9 to 15.

BRIEF DESCRIPTION OF THE DRAWINGS

Further characteristics and advantages of the system and method according to the invention will result from the following description of preferred embodiments, given by way of non-limiting example, with reference to the attached figures, in which:

figure 1 illustrates an embodiment of a system according to the present invention;

- figure 2 illustrates a detail of figure 1, according to an implementation option of the invention;

- figures 3 and 4 illustrate two respective further embodiments of the system of the invention;

- figure 5 ? a diagram representing a relationship between crank angle and valve lift, according to some profiles provided by the method according to the invention.

DETAILED DESCRIPTION

With reference to figures 1-5, a method is described for controlling the timing of at least one distribution valve 1 of the supply of an internal combustion engine.

This method comprises the phases of controlling an opening phase of the valve 1, determining a phase of maintaining the position of the valve 1 and carrying out a closing phase of the valve 1.

The aforementioned step of controlling an opening phase of the valve 1 comprises controlling the opening phase of the valve 1 by means of a mechanical coupling between the valve 1 and a rotating cam 2, so that the evolution of the opening of the valve 1 depends on a first portion of mechanical profile 21 of the cam and by the rotational movement of the cam 2.

The step of determining a phase of maintaining the position of the valve 1 comprises determining the phase of maintaining the position of the valve 1, at a desired moment of switching between opening and holding, corresponding to a desired opening position of the valve 1, by actuating retaining means 3 comprising an electromagnet 30 and mechanical holding means 31, mechanically coupled to the electromagnet 30 and mechanically coupled to the valve 1, when the electromagnet 30 is? operated.

This determining step comprises mechanically uncoupling the valve 1 from the cam 2, by actuating the electromagnet 30 and the consequent movement of the mechanical holding means 31, at the aforementioned moment of switching between opening and holding, so that the valve 1 is kept open in the desired open position, by an action of the aforementioned mechanical holding means 31.

The step of carrying out a closing step of the valve 1 comprises carrying out the closing step of the valve 1, at a desired moment of switching between holding and closing, by releasing the retaining means 3, determined by de-energizing the electromagnet 30 , which causes a decoupling between the mechanical retaining means 3 and the valve 1 and allows a subsequent mechanical coupling of the valve 1 to the cam 2, so that the evolution of the closure of the valve 1 depends, at least in part, on a second portion profile 22 of cam 2 and by the rotational movement of cam 2 itself.

According to an embodiment of the method, the valve timing angles, i.e. the valve opening and closing angles, i.e. the ratios between the valve closing and opening times, with respect to the valve cycle time, are determined by the aforementioned moment of switching between opening and holding and moment of switching between holding and closing.

In accordance with an embodiment of the method, the aforementioned first portion 21 and second portion 22 of the mechanical profile of the cam 2 belong to the overall mechanical profile of the cam 2.

According to an embodiment of the method, the aforementioned action of carrying out a closing step of the valve 1 comprises: a first sub-step, in which the valve 1 is closed; pushed towards the closure by a spring 5 or other elastic means coupled to the valve 1, in a condition in which it is not closed? the mechanical coupling with the second mechanical profile 22 of the cam has still been achieved; and a second sub-phase, in which the valve 1 has reached the condition of mechanical coupling with the second profile 22 of the cam 2.

In particular, in an implementation option, the closing profile of the valve 1 initially depends on the medium interposed between the cam 2 and the valve 1 (for example, hydraulic tappet) and then on the profile of the cam 2.

According to an implementation option, the valve closing profile depends first on the valve release dynamics (for example, when valve 1 is released, the tappet must first be compressed and this does not depend on the cam profile), then it depends on a part or all of the profile of the cam 2 according to the moment in which the electromagnet 30 is released.

According to an implementation option, the second profile 22 of cam 2 is only partially exploited.

According to one embodiment of the method, the valve 1 is mechanically coupled to the cam 2 by a hydraulic tappet element 310 and a first end of a rocker arm 311, in which a first portion of the hydraulic tappet element ? adapted to be placed in contact with the cam 2 and a second portion of the hydraulic tappet element ? adapted to be placed in contact with the aforementioned first end of the balance wheel 311.

In that case, the first extreme of the 311 balance wheel ? adapted to be placed in contact with a head of the valve and a second end of the rocker arm 311 ? adapted to be mechanically coupled to the retaining means 3.

According to an implementation option of the method, the aforementioned retention means 3 comprise the aforementioned rocker arm 311, a rod 312 placed in contact with the second end of the rocker arm 311, a mobile armature of the electromagnet 303 integral with the aforementioned rod 312, and furthermore an electromagnet core 301, which can be energized and/or controlled by means of an electromagnet coil 302, able to control the actuation of the electromagnet 30.

In accordance with one embodiment of the method, the valve 1 is an inlet valve or an exhaust valve of a cylinder of an internal combustion engine.

In accordance with one embodiment, the steps of the method are applied to each of the intake and exhaust valves of each of the cylinders of an internal combustion engine.

Hereinafter described, with reference to figures 1, 3 and 4, a system 100 for controlling the timing of at least one distribution valve 1 of the supply for internal combustion engines, capable of carrying out the previously described method.

This system 100 comprises a cam 2, retention means 3 and control means 4.

Cam 2? configured to rotate in a controlled manner, and has a profile comprising a first portion of mechanical profile 21 of cam 2 and a second portion of mechanical profile 22 of cam 2.

The retaining means 3 comprise an electromagnet 30, which can be energized in a controlled manner, and furthermore mechanical holding means 31, mechanically coupled to the electromagnet 30 and which can be coupled mechanically to the valve 1, when the electromagnet 30 is? operated, in a controlled manner.

The control means 4 of the system 100 are operatively connected to the aforementioned cam 2 and to the aforementioned retention means 3.

The control means 4 are configured to carry out the following operations:

- control an opening phase of the valve 1 by means of a mechanical coupling between the valve 1 and the rotating cam 2, so that the evolution of the opening of the valve 1 depends on the aforementioned first portion of the first mechanical profile 21 of the cam and on the movement rotation of cam 2;

- energizing said electromagnet 30 of the retaining means 3 in a controlled manner, so as to consequently actuate the mechanical holding means 31, imposing a movement on the mechanical holding means 31 capable of determining a phase of maintaining the position of the valve 1, in a desired moment of switching between opening and holding, corresponding to a desired opening position of the valve 1.

The aforementioned operation of determining the phase of maintaining the position of the valve 1 comprises a mechanical decoupling of the valve 1 from the cam 2, due to the aforementioned movement of the mechanical maintenance means 31, at the moment of switching between opening and maintenance, so that the valve 1 is kept open in the desired open position;

The control means 4 are also configured to de-energize the electromagnet 30 of the retaining means 3 in a controlled manner so as to consequently actuate the mechanical holding means 31, imposing a release on the mechanical holding means 31 capable of carrying out a phase closing of the valve 1, at a desired moment of switching between holding and closing.

The aforementioned operation of carrying out the closing phase of the valve 1 comprises a decoupling between the mechanical retention means 3 and the valve 1 and a subsequent mechanical coupling of the valve 1 to the cam 2, so that the evolution of the closing of the valve 1 depends at least in part by the second portion of the mechanical profile 22 of the cam 2 and by the rotational movement of the cam 2.

According to an embodiment of the system, the aforementioned electromagnet 30 of the retaining means 3 comprises an electromagnet core 301, which can be energized and/or controllable by means of an electromagnet coil 302, suitable for controlling the actuation of the electromagnet 30, and further comprises an electromagnet movable armature 303.

In accordance with an embodiment of the system 100, the mechanical holding means 31 comprise a hydraulic tappet element 310, operatively connected to the electromagnet 30 and to the cam 2, and configured to couple or uncouple the cam 2 from the valve 1, on the basis of the energization or otherwise of the electromagnet 30.

According to an implementation option, the mechanical holding means 31 further comprise a rocker arm 311, having a first rocker arm end operatively connected to the movable armature 303 of the electromagnet, so that a movement of the movable armature 303 of the electromagnet 30 determines a corresponding movement of the rocker arm 311, and having a second rocker arm end operatively connected to the valve 1.

Furthermore, one of the two extremes of the 311 ? operatively connected with the aforementioned hydraulic tappet element 310.

According to an implementation option of the system, the mechanical holding means 31 further comprise a rod 312 integral with the movable armature 303 of the electromagnet, to which connected at a first rod end, and connected with the first rocker arm end 311 at a second rod end.

In accordance with an embodiment of the system 100, illustrated for example in figure 1, the balance wheel 311 is operatively connected to the hydraulic tappet element 310 at the aforesaid second extreme of the rocker arm which ? also operationally connected with valve 1.

In accordance with another embodiment of the system 100, illustrated for example in figure 3, the balance wheel 311 is operatively connected to the hydraulic tappet element 310 at said first rocker arm end which ? also operatively connected with the electromagnet movable armature 303.

According to an embodiment of the system 100, illustrated for example in figure 4, the hydraulic tappet element 310 is? connected to the cam 2, at a first portion of hydraulic tappet element 310, and ? connected to the electromagnet movable armature 303, at a second portion of hydraulic tappet element.

In this case, the movable electromagnet armature 303 ? adapted to be operatively connected to a closing spring 5 of the valve.

Some embodiments of the system according to the present invention are described in greater detail below.

In the embodiment described in Figure 1, the system 100 is consisting of a traditional poppet valve 1 with relative closing spring 5, a rocker arm 311, a hydraulic tappet 310, a cam 2, a rod 312 and a holding electromagnet 30.

Consider initially the case in which the valve 1 is in rest conditions, corresponding to a situation of ?closed valve?, and in which the hydraulic tappet 310 ? in contact with cam 2 in the portion with the smallest radius ?heel?.

In this condition, the small piston 60 of the hydraulic tappet 310 (of which an implementation option is shown in detail in Figure 2) closes the outflow port 61.

The three phases of opening, holding and closing of the valve in this embodiment are now described in detail.

OPENING PHASE

During the opening phase of the valve 1, the rotating cam 2 pushes, through the end? of the rocker arm 311, the hydraulic tappet 310 determining the opening of the valve 1. This happens because? the piston 60 closes the outflow port 61, it cannot? then scroll further inside the cylinder 62 of the hydraulic tappet 310 due to the incompressibility? of the oil and the consequent increase in the oil pressure in the pressure chamber 63.

In these conditions, the valve 1 therefore follows the opening profile of the cam 2 since? the hydraulic tappet 310 you can't? compress.

The rocker arm 311, also pushed by the hydraulic tappet 310, in turn pushes, from its end, opposite, the movable armature 303 of the electromagnet 30 towards the pole piece of the fixed core 301 of the electromagnet 30, through the rod 312 or even by direct connection.

In this implementation option, the dimensions of the parts of the system are dimensioned so that the valve 1 reaches the maximum lift in correspondence with the condition in which the hydraulic tappet 310 ? in contact with the tip of the cam 2. In this condition the pole pieces of the mobile armature 303 and of the fixed core 301 of the electromagnet 30 are in contact and the speed? of the valve and of the core are substantially nil.

As illustrated in Figure 5, throughout the opening phase the valve lift graph follows the normal profile of the cam.

MAINTENANCE PHASE

The electromagnet 30 is powered so as to keep the valve 1 open regardless of the closing profile of the cam 2, so to anticipate or delay the subsequent closing phase regardless of the closing profile imposed by cam 2.

To obtain this effect, in the embodiment considered here, the magnetic attraction force must generate a torque, which acts on the rocker arm 311, greater than the torque generated by the closing spring 5 of the valve 1 in the maximum opening position.

Valve 1 remains open as long as? the electromagnet 30 is powered.

The angular interval of maintenance is chosen according to the optimal operating conditions of the engine at the different speeds of rotation, and can? be easily and effectively controlled simply by controlling the power supply time (i.e. energization, i.e. actuation) of the electromagnet 30.

In any case, during the holding phase, the cam 2 continues to rotate, causing an expansion of the hydraulic tappet 310. This expansion takes place thanks to the internal spring 64 of the hydraulic tappet, which pushes both the piston 60 and the cylinder 62 towards the cam 2 and towards the balance wheel 311.

In this condition, the oil flow inside the cylinder 62 passes through the non-return valve 65, which opens due to the depression created during the expansion.

Furthermore, the piston 60 opens the outflow port 61 favoring the flow of oil from the tank 66 towards the pressure chamber 63.

In this implementation option, the oil required for operation is accumulated in a tank 66 which is filled through the engine oil inlet port 67. The oil used is? the same oil from the engine lubrication circuit which flows through the tappet from the engine oil inlet port 67 to the engine oil outlet port 68.

As illustrated in Figure 5, during the holding phase the valve lift, due to the retention, does not follow the closing profile of the cam.

Conversely, if the electromagnet 30 were not powered during the holding phase, the valve 1 would follow the closing profile of the cam 2 which can? be normal or anticipated.

Of course, there? ? possible, if desired, by reducing the maintenance phase to zero duration, or to a negligible time.

CLOSING PHASE

The closing phase of the valve 1 takes place by de-energizing the electromagnet 30 (that is, cutting off the power supply to the electromagnet).

The electromagnet 30 is de-energized according to the advance and delay of the closing phase to be obtained.

Following the de-energization of the electromagnet 30, the valve 1 closes due to the effect of the closing spring 5 of the valve which expands.

The closing spring 5 determines the compression of the hydraulic tappet 310. During the compression, the oil flows out through the outflow port 61 until the piston 60 closes the port itself.

In this condition, the valve 1 follows the profile of the cam 2, being unable to further compress the tappet 310 due to the incompressibility? oil and as a result of the increase in oil pressure in the pressure chamber.

It should be noted that, in this particular embodiment, for the correct functioning of the system ? The expansion force of the valve closing spring 5 must always be greater than the expansion force of the hydraulic tappet spring.

Also note that the maintenance phase can last even beyond 180? the crank angle, as represented by the dotted line in Figure 5.

With reference to figures 3 and 4, some further embodiments of the system are illustrated, which in any case operate in a similar way to the embodiments previously described.

In Figure 3, the hydraulic tappet 310 pushes the rocker arm 311 from the same side where ? connected the mobile armor 303. The effect? the same as the configuration described in figures 1 and 2, that is? opening of the valve 1 and approaching of the pole pieces of the movable armature 303 and of the fixed core 301 of the electromagnet 30; same? also the operation of the 310 hydraulic tappet.

In the embodiment illustrated in Figure 4, it is not a rocker arm is provided, and the hydraulic tappet 310 directly pushes the movable armature 303, which simultaneously pushes the valve 1.

Also in this case, the approaching of the pole pieces and the opening of the valve 1 are obtained, same? also the operation of the tappet 310.

In the latter embodiment, the constructive difference consists in the fact that the stem of the valve 1 passes through the fixed core 301 of the electromagnet 30, and furthermore the closing spring 5 of the valve 1? positioned inside the electromagnet 30.

How can you? ascertaining, the objects of the present invention, as previously indicated, are fully achieved by the method described above, by virtue of the characteristics described above in detail.

Among the advantages obtained by means of the method of the present invention, the following can be mentioned, among others.

In general, the system according to the invention, described above, is extremely flexible: in fact, both the opening phase and the closing phase are determined simply by energizing the opening and closing electromagnet respectively without any mechanical constraint linked to the profile of the eccentric, or rather of the cam.

Furthermore, the solution described above in the present disclosure allows the following technical problems to be solved and the following technological limits encountered in the known art to be overcome.

The proposed system uses an eccentric during the valve opening phase so that the electromagnet does not consume any energy. After the opening phase there is a phase called maintenance in which a holding electromagnet keeps the valve open thus determining? the advance or delay of the subsequent closing phase. Basically, the opening of the valve ? regulated by the profile of the cam while the closure ? regulated by?electromagnet with the possibility? to adjust both the advance and the closing delay on a considerable overall angular interval, or crank angle (over 180?).

The holding electromagnet always acts in the optimal condition with substantially zero D (maximum force).

Furthermore, the electromagnet does not act as in existing systems to accelerate and decelerate the masses but only to keep the valve open. The problem of decelerating the motion of the mobile armature during the attraction is also solved, since? the attraction occurs only when the valve ? completely open and its speed? ? essentially nothing. Not ? therefore, no further deceleration device is necessary, which would increase bulk and costs.

In addition, the possibility of varying the closing phase of the valves, offered in a simple and effective way by the present invention, determines the following further advantages:

- optimization of the volumetric efficiency at low, medium and high speeds by adjusting the advance or delay of the closing phase of the intake valve;

- at low and medium loads, the regulation of the delay of the closing phase of the exhaust valve determines the intersection with the opening phase of the intake valve and allows the reduction of polluting emissions by exploiting the backward flow of the exhaust gases due to the vacuum in the intake manifold;

- the regulation of the delay of the closing phase of the exhaust valve optimizes the torque at low speed? and power at high rpm;

- at low and medium operating speeds, early closure of the intake valve favors better mixing of the air-fuel mixture with an increase in efficiency and a reduction in pollutants;

- the advance or delay of the closing phase of the intake valve allows the implementation of the Miller cycle with significant increases in efficiency;

- moreover, the large crank angle (over 180?) with which ? possible to regulate the delay of the closing phase of the intake valve, according to the present invention, ensures the further important advantage of being able to regulate the pressure ratio r = Ps/Pi, where Ps ? the pressure inside the cylinder at the end of the compression phase, and Pi ? the pressure inside the cylinder at the beginning of the compression stroke.

By delaying the closure of the intake valve, ? It is possible to vary the ratio r in order to optimize the thermodynamic efficiency as a function of the octane number of the fuel.

In spark-ignition bi-fuel petrol-methane engines? possible to increase the compression ratio beyond the values typically used 8 ? 12 to favor the efficiency of the thermodynamic cycle. Using methane as a fuel with a higher octane number, the higher compression ratio of the engine and the higher r ratio are exploited without incurring the phenomenon of detonation, but at the same time ? It is possible to use the same petrol-powered engine, reducing the ratio r so as not to incur the phenomenon of detonation. This allows the development of innovative engines with high thermodynamic efficiency with low polluting fuels.

A further advantage of the present invention ? that in the event of a failure of the coil of the electromagnet of retention, the engine can? still work (even if without the advantages described previously) making the system intrinsically reliable, while in known systems of the ?camless? with electromagnetic actuators the motor would block.

To the embodiments of the method described above, a person skilled in the art, in order to satisfy contingent needs, will be able to make modifications, adaptations and replacements of elements with other functionally equivalent ones, without departing from the scope of the following claims. Each of the characteristics described as belonging to a possible embodiment can? be made independently of the other described embodiments.

Claims (15)

1. Method for checking the timing of at least one distribution valve (1) of the supply of an internal combustion engine, including the steps of: - control an opening phase of the valve (1) by means of a mechanical coupling between the valve (1) and a rotating cam (2), so that the evolution of the opening of the valve (1) depends on a first portion of the profile (21) mechanical of the cam and by the rotational movement of the cam (2); - determining a phase of holding the position of the valve (1), at a desired moment of switching between opening and holding, corresponding to a desired opening position of the valve, by actuating retaining means (3) comprising an electromagnet (30) and mechanical holding means (31), mechanically coupled to the electromagnet (30) and mechanically coupled to the valve (1), when the electromagnet (30) is? operated, wherein said determining step comprises mechanically uncoupling the valve (1) from the cam (2), by actuating the electromagnet (30) and the consequent movement of the mechanical holding means (31), at said switching moment between opening and holding, so that the valve (1) is kept open in said desired open position, by an action of said mechanical holding means (31); - carry out a closing phase of the valve (1), at a desired moment of switching between holding and closing, by releasing the retaining means (3), determined by de-energizing the electromagnet (30), which causes a decoupling between the mechanical holding means (31) and the valve (1) and allows a subsequent mechanical coupling of the valve (1) to the cam (2), so that the evolution of the closure of the valve (1) depends at least in part on a second portion of mechanical profile (22) of the cam (2) and by the rotational movement of the cam (2). The method according to claim 1, wherein the timing angles of the valve, i.e. the opening and closing angles of the valve, i.e. the ratios between the closing and opening times of the valve, with respect to the cycle time of the valve, are determined from said moment of switching between opening and holding and moment of switching between holding and closing. The method according to any one of claims 1 or 2, wherein said first portion (21) and second portion (22) of mechanical profile of the cam belong to the overall mechanical profile of the cam. 4. Method according to any one of the preceding claims, wherein said step of carrying out a closing step of the valve (1) comprises: - a first sub-phase, in which the valve (1) ? pushed towards closure by a spring (5) or other elastic means coupled to the valve, in a condition in which it does not ? the mechanical coupling with the second portion of the mechanical profile (22) of the cam (2) has still been achieved; - a second sub-phase, in which the valve (1) has reached the condition of mechanical coupling with the second profile portion (22) of the cam. 5. Method according to any one of the preceding claims, wherein the valve (1) is mechanically coupled to the cam (2) by a hydraulic tappet element (310) and a first end of a rocker arm (311), wherein a first portion of the hydraulic tappet element ? adapted to be placed in contact with the cam (2) and a second portion of the hydraulic tappet element ? adapted to be placed in contact with said first end of the balance wheel (311), and in which said first end of the balance wheel (311) ? adapted to be placed in contact with a valve head, and in which a second end of the balance wheel (311) ? adapted to be mechanically coupled to the retaining means (3). 6. A method according to any one of the preceding claims, wherein the valve (1) is an inlet valve or an exhaust valve of a cylinder of an internal combustion engine. 7. Method according to any one of the preceding claims, applied to each of the intake and exhaust valves of each of the cylinders of an internal combustion engine. 8. System (100) for controlling the timing of at least one fuel distribution valve (1) of an internal combustion engine, comprising: - a cam (2) configured to rotate in a controlled manner, having a mechanical profile (21, 22) comprising a first cam mechanical profile portion (21) and a second cam mechanical profile portion (22); - retaining means (3) comprising an electromagnet (30), which can be energized in a controlled manner, and furthermore mechanical holding means (31), mechanically coupled to the electromagnet (30) and mechanically coupled to the valve (1), when the electromagnet (30) ? operated, in a controlled manner; - control means (4), operatively connected to said cam (2) and to said retention means (3), wherein said control means (4) are configured for: - control an opening phase of the valve (1) by means of a mechanical coupling between the valve (1) and said rotating cam (2), so that the evolution of the opening of the valve (1) depends on said first profile portion cam mechanic (21) and by the rotation movement of the cam (2); - energizing said electromagnet (30) of the retaining means (3) in a controlled manner so as to consequently actuate said mechanical holding means (31), imposing a movement of the mechanical holding means (31) capable of determining a phase of holding the position of the valve (1), at a desired moment of switching between opening and holding, corresponding to a desired opening position of the valve, wherein said determination of the valve position maintenance phase comprises a mechanical uncoupling of the valve (1) from the cam (2), due to said movement of the mechanical maintenance means (31), at said moment of switching between opening and holding, so that the valve (1) is kept open in said desired open position; - de-energizing said electromagnet (30) of the retaining means (3) in a controlled manner so as to consequently actuate said mechanical holding means (31), forcing a release of the mechanical holding means (31) capable of carrying out a phase of closing of the valve, at a desired moment of switching between holding and closing, wherein said performance of the valve closing phase comprises a decoupling between the mechanical retention means (3) and the valve (1) and a subsequent mechanical coupling of the valve (1) to the cam (2), so that the evolution of the closure of the valve depends at least in part on said second portion of the mechanical profile of the cam (22) and on the rotational movement of the cam (2). 9. System (100) according to claim 8, wherein the electromagnet (30) of the holding means (3) comprises: - an electromagnet core (301), energizable and/or controllable by means of an electromagnet coil (302), able to control the actuation of the electromagnet (30); - a mobile armature (303) of the electromagnet. 10. System (100) according to claim 8 or claim 9, wherein the mechanical maintenance means (31) comprise a hydraulic tappet element (310), operatively connected to the electromagnet (30) and to the cam (2), and configured to couple or uncouple the cam (2) to/from the valve (1), based on whether or not the electromagnet (30) is energized. The system (100) according to claim 10, wherein the mechanical holding means (31) further comprises a rocker arm (311), having a first rocker arm end operatively connected with said movable electromagnet armature (303), so that a movement of the movable armature (303) of the electromagnet determines a corresponding movement of the rocker arm (311), and having a second rocker arm end operatively connected with said valve (1), in which one of the two extremes of the balance wheel (311) ? further operatively connected with said hydraulic tappet element (310). 12. System (100) according to claim 11, wherein the mechanical maintenance means (31) further comprise a rod (312) integral with said movable armature (303) of the electromagnet, to which connected at a first rod end, and connected with said first rocker arm end at a second rod end. The system (100) according to claim 12, wherein the rocker arm (311) is operatively connected to the hydraulic tappet element (310) at said second rocker arm end which ? also operationally connected with the valve (1). The system (100) according to claim 12, wherein the rocker arm (311) is operatively connected to the hydraulic tappet element (310) at said first rocker arm end which ? also operatively connected with the electromagnet movable armature (303). The system (100) according to claim 10, wherein the hydraulic tappet element (310) is connected to the cam (2), at a first portion of the hydraulic tappet element, and ? connected to the electromagnet movable armature (303), at a second portion of hydraulic tappet element, and in which the mobile armature of electromagnet (303) ? adapted to be operatively connected with a closing spring (5) of the valve.