FR3084390A1 - OPENING HANDLE FOR A MOTOR VEHICLE PROVIDED WITH AN INERTIAL SAFETY SYSTEM - Google Patents

Abstract

The invention relates to a handle (1) of an opening (100) of a motor vehicle (101) comprising: a gripping lever (2) movable in rotation between a rest position and a control position for the opening of a door lock (100); a transmission lever (3) mounted in a base (4) of the handle (1) arranged to be fixed to the leaf (100), the transmission lever (3) being configured to be actuated by the gripping lever ( 2) and pivot between a rest position and an active position in which the transmission lever (3) actuates the opening of the lock; and a security system (5) mounted in the base (4), configured to prevent rotation of the transmission lever (3) in the event of an impact, the security system (5) comprising at least one inertial mass (6) mounted pivoting between a rest position and an active position preventing rotation of the transmission lever (5), the handle (1) being characterized in that it comprises a locking mechanism (10) configured to block the inertial mass (6) when it reaches the active position, and an unlocking mechanism (10) configured to unlock the inertial mass (6) when it is activated by actuation of the gripping lever (2).

Description

Motor vehicle window handle provided with an inertial safety system

The invention relates to a handle of a motor vehicle sash, in particular a handle of a side door, of the type provided with an inertial safety system.

To meet the various safety standards, in particular in the event of a side impact, the side handles of a motor vehicle currently known are equipped with an inertial system. This inertial system is triggered during a side impact on the door and blocks the gripping lever to prevent any untimely opening of the side door which could cause the passenger to be ejected from the vehicle.

These known handles include a gripping lever movable in rotation relative to the opening between a rest position and a control position. This gripping lever can act on a transmission lever which will actuate, via a linkage or cables such as Bowden cables for example, the opening of a lock on the sash.

The inertial system is composed in a known manner of an inertial mass and a blocking lug secured to this inertial mass, which cooperates with a shoulder of the transmission lever to block said lever in the event of a side impact in a position where it does not can not act to open the lock.

In known inertial systems, the inertial mass, in the active position, blocks the transmission lever either irreversibly or reversibly.

In the case of the reversible inertial system, the inertial mass is moved under the effect of an acceleration caused by a shock from an inactive rest position to an active position in which the inertial system blocks the transmission lever, then returns to its position. inactive when the acceleration is zero by being constrained by an elastic return means such as a spring.

Such a reversible type safety system is advantageous in that it allows, after an impact, to be able to make the handle accessible again, insofar as it was not destroyed during the accident. This type of safety system is also generally particularly reactive because the sensitivity of the movement of the inertial mass can be increased since this presents no risk during its normal use.

One of the drawbacks of such a reversible type safety system is the phenomenon of inertial mass rebounds. In fact, under the effect of the various abrupt variations in acceleration, while being constrained by the spring, the inertial mass will oscillate between its active and inactive positions: the actual behavior of the handle during the accident is therefore particularly difficult. predictable.

In the case of the irreversible inertial system, the inertial mass is moved under the effect of an acceleration caused by a shock from an inactive position to an active position in which the inertial system blocks the transmission lever, then remains blocked in this active positron.

This system is particularly advantageous in that it eliminates the possibility of rebounds of the inertial mass since it is locked in its active position.

However, one of the drawbacks of such an irreversible type safety system is that in the event of a slight impact, that is to say at low acceleration, or of accidents during assembly, the handle is found completely blocked. To avoid such a problem, the sensitivity of the displacement of the inertial mass is generally reduced. However, such sensitivity is detrimental in that it can trigger the inertial system too late.

The invention aims to solve all or part of these drawbacks by proposing a handle for a sash for a vehicle provided with an optimized inertial safety system which is both reversible and whose rebound phenomenon is eliminated.

To this end, the invention relates to a handle of a motor vehicle opening comprising:

- a movable gripping lever in rotation between a rest positron and a control position for opening a lock of the opening,

- a transmission lever mounted in a base of the handle arranged to be fixed to the leaf, the transmission lever being configured to be actuated by the gripping lever and pivot between a rest position and an active position in which the lever transmission actuates the opening of the lock, and

- a safety system mounted in the base, configured to prevent rotation of the transmission lever in the event of an impact, the safety system comprising at least one inertial mass pivotally mounted between a rest position and an active position preventing rotation of the lever transmission, the handle being remarkable in that it comprises a locking mechanism configured to block the inertial mass when it reaches the active position, and an unlocking mechanism configured to unlock the inertial mass when it is activated by actuation gripping lever.

Thanks to such a handle, the inertial mass is moved under the effect of an acceleration caused by a shock from an inactive position of rest to an active position in which the inertial system blocks the transmission lever by means of the mechanism of blocking then, under the action of a predetermined force on the gripping lever which activates the unlocking mechanism, the inertial system is released and returns to the rest position.

The removal of the blockage of the inertial system thus allows, after this release, the return of the inertial mass to its rest position and can then be reused.

Indeed, the unlocking of the inertial mass by the unlocking mechanism consists in releasing the inertial mass from its active position then constrained and blocked by the blocking mechanism. The inertial mass, once released from this blocking constraint, will then return to its rest position.

Such an inertial system has all the advantages of reversible and irreversible inertial systems without the associated disadvantages. In this way, the locking mechanism can be reset, and can easily be reset manually by manual action on the gripping lever controlling the unlocking mechanism.

According to an advantageous characteristic, the locking mechanism and the unlocking mechanism are formed by all or part of the same locking and unlocking mechanism. Preferably, this mechanism is reversible between the locking position and the unlocking position.

In this way, the same locking and unlocking mechanism has a reduced size and the reduction in the number of mechanisms also allows a reduction in the manufacturing cost.

According to a particular technical characteristic, the locking and unlocking mechanism is configured so that the actuation of the gripping lever, in the blocking position of the inertial mass, causes it to be unlocked beyond a predetermined unlocking force on the handle. , this release force being greater than an average force for opening the handle.

In other words, the manual action applied to the gripping lever to unlock the security system is more intense than that to simply open the door of the vehicle.

According to an advantageous characteristic, the unlocking mechanism is activated by repeated actuation of the gripping lever. In other words, the security system, and in particular the inertial mass, is unlockable by repeated actuation of the gripping lever.

Thus, the user must actuate the gripping lever several times in order to unlock the security system. In this way, there is no confusion between the opening gesture of the opening and that of unlocking the security system.

According to another technical characteristic, the actuation of the gripping lever to activate the unlocking mechanism corresponds to a displacement of said gripping lever from its rest position to its control position for opening the lock of the door.

In this way, it is not necessary to configure the handle so that it has a degree of mobility and the unlocking mechanism uses, during unlocking, the pre-existing pivot link for the rotational mobility of the gripping lever between its position and its control position.

According to another characteristic, the security system comprises a locking lug secured to the inertial mass, which cooperates with a shoulder of the transmission lever when the inertial mass is in the active position, the shoulder of the transmission lever having a contact surface. configured to move the locking lug forming a follower when the transmission lever is pivoted, the inertial mass being released from the locking mechanism after a predetermined displacement of the inertial mass.

In a particular technical configuration, the locking and unlocking mechanism is a ratchet system.

Advantageously in this case, the locking and unlocking mechanism comprises a pawl configured to cooperate with a toothed wheel, the toothed wheel being integral with the inertial mass and in that the displacement of the locking lug forming a follower when the lever transmission is pivoted allows the release of the locking mechanism after a movement such that the toothed wheel is released from its cooperation in engagement with the pawl.

According to a particular characteristic, the handle comprises an elastic return means such as a return spring for resiliently returning the inertial mass 6 to the rest position, said return spring preferably being of the torsion spring type.

According to another advantageous characteristic, the blocking and unblocking mechanism is constrained by an energy storage means such as a compression spring.

In the case where the locking and unlocking mechanism is a ratchet system, this energy storage means is for example a compression spring and makes it possible to constrain and maintain the toothed wheel of the inertial mass against the ratchet.

In general, the blocking and unblocking mechanism such as the ratchet system is positioned, preferably interposed, between the inertial mass return means on the one hand, and by the energy storage means of somewhere else.

Other characteristics and advantages of the invention will emerge on reading the description which follows, given solely by way of example, with reference to the appended figures, which illustrate:

Figure 1, a diagram of a motor vehicle comprising an opening, such as a side door, provided with a handle according to the invention;

- Figure 2, a perspective view of part of a door handle of a motor vehicle according to one embodiment of the invention;

Figures 3A, 3B, 3C and 3D, perspective views of a transmission lever with a counterweight according to this embodiment;

- Figure 4, a view of a locking and unlocking mechanism according to this embodiment;

- Figure 5, a perspective view of a counterweight of the transmission lever according to this embodiment;

FIGS. 6A, 6B and 6C, perspective views of an inertial mass according to this embodiment;

- Figures 7A and 7B, perspective views of a pawl 7 according to this embodiment;

- Figures 8A, 8B, 8C and 8D, views of a locking and unlocking mechanism in a rest position, according to one embodiment;

- Figures 9A, 9B, 9C and 9D, views of a locking and unlocking mechanism during an accident, according to this embodiment;

- Figures 10A, 10B, 10C and 10D, views of a locking and unlocking mechanism after an accident during a first movement of opening of the handle, according to this embodiment;

FIGS. 11A, 11B, 11C and 11D, views of a locking and unlocking mechanism after an accident during a first release of the handle, according to this embodiment;

FIGS. 12A, 12B, 12C and 12D, views of a blocking and unblocking mechanism after an accident during a second movement of opening of the handle, according to this embodiment;

- Figures 13A, 13B, 13C and 13D, views of a locking and unlocking mechanism after an accident during a second release of the handle, according to this embodiment;

- Figures 14 and 15, views of a locking and unlocking mechanism according to another embodiment.

In the present application, the terms “top”, “bottom”, “upper”, “lower”, “horizontal”, “vertical”, and their derivatives refer to the position or the orientation of an element or d 'a component, this position or orientation being considered when the vehicle is in service configuration on horizontal ground.

In addition, to clarify the description and the claims, the longitudinal, vertical and transverse terminology will be adopted without limitation, with reference to the trihedron L, V, T indicated in the figures.

In all of these figures, identical or analogous references represent identical or analogous organs or assemblies of organs.

Note that in the present patent application, the terms "front" and "rear" must be understood with respect to the general longitudinal direction of the vehicle, that is to say from the left to the right of FIG. 1 .

There is shown in Figure 1 an external handle 1 for an opening 100 of a motor vehicle 101, according to the invention.

The opening 100 is delimited by an external face 110 which is arranged outside the vehicle 101.

FIG. 2 represents a perspective view of a handle 1 of the opening 100 of a motor vehicle, in particular of a side door.

The opening handle 1 comprises a gripping lever 2 accessible from outside the vehicle and on which a user pulls outwards to open the door.

This gripping lever 2 is connected to a fixed part 4, also called base 4 or handle support 1, which is intended to be fixed to the opening 100, in particular mounted inside the opening 100, and more precisely still behind the external face 110 of the door, and which is therefore not visible once mounted on the vehicle 101.

More particularly, this gripping lever 2 is movable in rotation and can pivot around a first vertical axis of rotation Z between a rest position and a control position for the opening of a lock of the opening leaf 100, when the user pulls this gripping lever 2. This first axis of rotation Z is substantially parallel to the axis of rotation of the door

An embodiment of this base 4 is shown in FIG. 2 showing a perspective view of the rear of the handle 1, in particular of its base 4.

The base 4 is for example made by injection into a plastic material or into a die-cast metal.

The base 4 includes a transmission mechanism for connecting the gripping lever 2 to the door opening mechanism 100 and an inertial security system 5 to prevent any untimely opening of the opening in the event of an impact.

The transmission mechanism comprises a transmission lever 3 provided with a counterweight 30 'and mounted in a housing of the base 4 of the handle 1.

This transmission lever 3 is configured to be actuated by the gripping lever 2 and is pivotally mounted, around a second axis of rotation A, between a rest position and an active position in which the transmission lever 3 actuates the opening the lock.

Furthermore, the transmission mechanism is connected to an actuation cable 8, such as a Bowden cable, connected to the mechanism of the door 100, more precisely to the lock (not shown).

Thus, when the transmission lever 3 moves to the active position, the cable actuates the opening of the lock.

A return spring 33, for example of the helical torsion spring type, makes it possible to return the transmission lever 3 to the rest position.

In particular in this embodiment, the transmission lever 3 is composed in particular of the assembly of two parts or elements (visible in FIGS. 3A to 3D):

a first part 30 comprising a cooperation interface arranged to be activated by the gripping lever 2,

- a second part forming a counterweight 30 and having an interface for fixing one of the ends of the actuation cable provided for actuating the opening of the lock.

These two parts 30, 30 'are integral with each other, once assembled, so that the pivoting of the first part driven by the gripping lever 2 causes in its movement the pivoting of the interface for fixing the cable for applying to said cable a sufficient tensile force to actuate the opening of the lock.

These two parts 30, 30 'are made of two separate materials so as to optimize the counterweight function provided by the second part 30. For example, the first actuated part 30' can be made of plastic while the second part 30 forming a counterweight metallic preference.

For the assembly of the transmission lever 3, the different parts are assembled as follows:

the return spring 33 is first positioned on one of the parts 30, 30 'of the transmission lever 3, in particular on the first part 30', by being inserted in an insertion direction Fi and positioned coaxially around 'a cylindrical end of this said first part 30' (see FIG. 3A),

the second part 30 forming a counterweight is then brought together laterally radially and attached to the first part 30 ′ (see FIG. 3B),

- The first and second parts 30, 30 ′ are then translated axially with respect to each other (see FIG. 3C) so as to insert fixing lugs 34 into holes 35 provided for this purpose (see FIG. 3D) ensuring their maintenance.

The security system 5 is configured to prevent rotation of the transmission lever 3 in the event of an impact and is mounted for rotation in the base 4.

This security system 5 comprises an inertial mass 6 articulated on the base 4 or a part integral with this base 4. As can be seen in FIG. 2, the inertial mass 6 extends along a horizontal axis, here the longitudinal axis gripping lever 2.

This inertial mass 6 is pivotally mounted, relative to the base 4, around a third axis of rotation B between a rest position and an active position in which the transmission lever 3 is locked in rotation.

In this embodiment, the inertial mass 6 indirectly blocks the gripping lever 2, via the blocking of the transmission lever 3. However, provision could be made for the inertial mass 6 to directly block the gripping lever 2.

According to this embodiment, this third axis of rotation B is substantially parallel to the second axis A and substantially parallel to the first axis of rotation Z.

In addition, a return spring 9 (see FIG. 4), for example of the helical type, makes it possible to return the inertial mass 6 to the rest position.

The inertial mass 6 is shaped to pivot when it undergoes strong accelerations, for example of the order of 30 G (IG corresponds to 9.80665 ms ² ).

This inertial mass 6 carries at one end a locking pin 61 which cooperates with a shoulder 31 of the transmission lever 3 during the pivoting of the inertial mass 6.

During normal opening of the door 100, the transmission lever 3 is rotated without the locking pin 61 touching the shoulder 31, the inertial mass 6 remaining stationary in the rest position (Figure 3a). Indeed, the inertial mass 6 being stationary, the locking pin 61 remains erased from the rotational travel of the transmission lever 3, that is to say that it is not in the path of the shoulder 31.

On the other hand, in the event of an impact, if the gripping lever 3 undergoes a force which would tend to open, the inertial mass 6 will also be subjected to the same force, so that the inertial mass 6 pivots driven by the force of inertia, overcoming the force of its return spring 9. The locking pin 61 is then moved until intercepting the shoulder 31 and locking the transmission lever 3 at the start of rotation of the transmission lever 3.

According to the invention, the handle 1 comprises a locking mechanism 10 configured to block the inertial mass 6 when it reaches the active position, and an unlocking mechanism 10 configured to unlock the inertial mass 6 when it is activated by actuation gripping lever 2.

The easy removal of the blocking of the inertial mass 6 by the actuation of the gripping lever 2 thus allows, after its release, the return of the inertial mass 6 to its rest position, the safety system 5 can then be reused normally.

The release of the inertial mass 6 by the release mechanism 10 consists in releasing the inertial mass from its active position which is then constrained and blocked by the blocking mechanism 10. The inertial mass 6, once released from this blocking constraint by the actuation of the gripping lever 2, then returns to its rest position.

Such an inertial system has all the advantages of reversible and irreversible inertial systems without the associated drawbacks, namely in particular that of having improved reactivity due to the increased sensitivity of the movement of the inertial mass 6 both by effectively eliminating the possibility of rebounds inertial mass 6 since it is blocked in its active position in the event of an impact.

Furthermore, the locking mechanism being reinrtialisable by actuation of the unlocking mechanism itself actuated by the gripping lever 2, it can easily be reset by manual action on said gripping lever 2 which controls the unlocking mechanism. Such an action can be easily implemented by a user of the vehicle and does not require the intervention of a qualified person, as is the case for irreversible inertial systems known from the prior art.

Preferably, as is the case in this embodiment, the locking mechanism and the unlocking mechanism are formed at least in part by the same locking and unlocking mechanism 10.

In this way, the handle 1 is not weighed down or complicated in its manufacture and assembly by the presence of two completely separate mechanisms.

In particular, this locking and unlocking mechanism 10 is reversible between the locking position and the unlocking position.

In the embodiment illustrated in these figures, the locking and unlocking mechanism 10 is a ratchet system.

The inertial mass 6 is pivotally connected to the base 4 by means of a fixing pin 12. The fixing pin 12 has the shape of a cylindrical shaft held at its ends by two bearings formed in walls 40 of the base 4.

The ratchet system forming a locking and unlocking mechanism 10 comprises a pawl 7 configured to cooperate with a toothed wheel 60, the toothed wheel 60 being integral with the inertial mass 6.

The pawl 7 has a tubular part 73 configured to cooperate in rotation with the spindle 12.

In other words, the fixing pin 12 is housed in a cylindrical orifice in the tubular part 73 of the pawl 7, so that said tubular part 73 is arranged coaxially with respect to the fixing pin 12.

The pawl 7 also has a disc 70 projecting radially from the tubular part 73. The disc has a contact surface 72 from which teeth 71 project axially from the axis of rotation B.

The inertial mass 6 has a base comprising a tubular part 63. This tubular part 63 of the inertial mass 6 configured to cooperate in rotation with the pawl 7, in particular with a cylindrical part of the tubular part 73 of said pawl 7.

In other words, a cylindrical part of the tubular part 73 of the pawl 7 is housed in a cylindrical orifice of the tubular part 63 of the inertial mass 6 so that said tubular part 63 is disposed coaxially with respect to the part cylindrical of the pawl 7, itself arranged coaxially with respect to the fixing pin 12.

The security system 5 comprises a toothed wheel 60 secured to the inertial mass 6 and having the shape of a disc projecting radially with respect to its tubular part 63. This toothed wheel or disc has a contact surface 62 at which notches are arranged axially with respect to the axis of rotation 10 B.

The contact surface 62 of the inertial mass 6 and the contact surface 72 of the pawl 7 are arranged opposite one another so that they face each other and are in contact together in at least the rest position, the teeth 71 of the pawls 7 being configured to penetrate into the notches 60 of the inertial mass 6.

^The discal of ^them elements 60, 70 of the locking mechanism and unlocking 10 are kept in contact and in abutment against each other at their contact surfaces 62, 72 through elastic means such as springs .

One of the springs is the return spring 9 of the inertial mass 6, of the torsion spring type, making it possible to return the inertial mass 6 to the rest position. It is located on a tubular part of the pawl 7 between, and even interposed between, one of the walls of the base 4 forming a bearing to the fixing pin 12 and the disc 70, on the opposite side of its contact surface 72.

The other return means is a compression spring 11 forming an energy storage means located between, and even interposed between, the other wall of the base 4 forming a bearing and the toothed wheel 60, on the opposite side of the surface. contact 62 carrying the notches 60.

In other words, the locking and unlocking mechanism 10, in particular the ratchet system is positioned, more precisely interposed, between the return means 9 of the inertial mass 6 on the one hand, and by the spring 11 of 30 compression forming energy storage means on the other hand, this axially with respect to the third axis of rotation B.

When I use the locking mechanism, when the inertial mass pivots by a certain angle, the notches 72 of the pawl 7 will come into engagement with the notches of the toothed wheel, this against the action of the compression spring 11 which tends to 35 maintain the two contact surfaces 62, 72 in abutment against each other.

To do this, the teeth and notches are configured to have a slope

I one with respect to the other sufficient for the sliding of a tooth on a notch to allow the cooperation of the teeth in the notches when the inertial mass is moved towards its active position.

These same notches are configured to prevent, once this active position is reached and this configuration of effective cooperation, the reversal of the inertial mass 6 despite the action of the return spring 9: in this way the blocking mechanism blocks the inertial mass 6 when it reaches the active position.

Furthermore, the shoulder 31 of the transmission lever 3 has a contact surface 32 of the transmission lever 3 configured so as to move the locking pin 61 of the inertial mass 6 forming a follower when said transmission lever 3 is pivoted, the inertial mass 6 being released from the locking mechanism 10 after a predetermined displacement of the inertial mass 6.

In particular, when using the unlocking mechanism, the movement of the locking pin 61 forming a follower during a pivoting of the transmission lever 3 causes the axial movement relative to the axis B of the inertial mass 6 in the direction of a separation of the two contact surfaces 62, 72 thus allowing the release of the locking mechanism 10.

Such release of the locking mechanism occurs after a movement such that the toothed wheel 60 is released from its cooperation in engagement with the teeth 71 of the pawl 7.

In this embodiment, the actuation of the gripping lever 2 corresponds to a displacement of said gripping lever 2 from its rest position towards its control position.

The advantage of using such a ratchet mechanism is that it is possible to predetermine a repetition of the actuation of the gripping lever 2 to activate the release mechanism 10. In fact, depending on the number of notches and / or teeth, each obstacle formed by the notch and / or the tooth can be passed in the unlocking direction by a single movement of the gripping lever.

Several configurations are possible, such as using a notch and several teeth, or several notches and a tooth, or as many notches as teeth. The use of several notches with several teeth, in different numbers is also possible.

The presence of 2 notches, for example, ensures activation of the release mechanism by repeating twice the opening movement of the handle 1, namely the movement of the gripping lever 2 towards its control position.

The operation of the locking and unlocking mechanism 10 will be better understood with reference to Figures 8 to 13 illustrating the operation, at different stages, of this mechanism according to this embodiment.

FIGS. 8A, 8B, 8C, 8D illustrate views of a locking and unlocking mechanism in a rest position, according to the same embodiment as that illustrated in the previous figures.

In this rest position, the torsion spring 9 makes it possible to return the inertial mass 6 to the rest position while the compression spring 11 is rigid so as to work only along the vertical axis B. Furthermore, the torsion spring 9, in addition to working in torsion to return the inertial mass to the rest position 6 also works in compression and makes it possible to push in the direction F1 (see FIG. 8A) the pawl 7 against the toothed wheel 60, and maintains contact between these two parts.

FIGS. 9A, 9B, 9C, 9D illustrate views of this locking and unlocking mechanism 10 during an accident.

During an accident, due to the acceleration which occurs and the inertial forces which apply to the inertial mass 6, said inertial mass 6 pivots in the direction of the arrow Fs (see FIG. 9A, towards the rear by with reference to the figure) up to the blocking position, i.e. to its active position where it prevents the rotation of the transmission lever 3.

During this pivoting, the toothed wheel 60 secured to the inertial mass 6 pivots concomitantly following its movement, the two contact surfaces 62, 72 being in contact, so that its notches abut against the teeth 71 of the pawl 7.

The locking mechanism 10 is configured so that when the teeth 71 of the pawl 7 abut with a predetermined force against the notches of the toothed wheel 60, said toothed wheel 60, and more generally the inertial mass 6, is moved away from the disc 70 of said pawl 7 while continuing its rotation towards its active position.

A front side of the tooth (s) and a front side of the notches facing said teeth 71 in the rest position have contact and friction surfaces having an inclined orientation so as to allow sliding of the notches on the teeth 71 in this direction of rotation of the inertial mass towards its active position, this allowing the inertial mass 6 to continue its rotation towards its active position despite the presence of the teeth 71.

When the rotation of the inertial mass 6 has driven the toothed wheel 60 in its rotation so that its notches pivot on a certain angular sector beyond a threshold angular sector where the teeth 71 are placed on the path of the notches during the rotation , that is to say when the obstacle formed by the teeth 71 has been crossed by the notches of the toothed wheel 60, the stresses of the return springs 9 and 11 tackle, once this obstacle (formed by the teeth 71 ) passed the two elements together so that the teeth 71 of the pawl prevent the reverse rotation of the inertial mass 6. In fact, once the acceleration is zero, the torsion spring 9 returns the inertial mass to the rest position. However, the notches then abut against the teeth 71 which, on this rear side opposite the front side, block the return of the inertial mass 6.

FIGS. 10A, 10B, IOC, 10D, illustrate views of this same locking and unlocking mechanism 10 after an accident during a first movement of opening of the handle by an external user.

After the accident, when an external user tries to open the handle 1, the transmission lever 3, in particular the shoulder 31 located on the counterweight 30 ', comes into contact and abuts against the blocking lug 61 of the inertial mass 6, said transmission lever 3 then being blocked (the door therefore does not open).

If the outside user tries to exert a greater force, the transmission lever 3, in particular here its counterweight 30 ', pushes the inertial mass 6 in the axial direction F3 thanks to the inclined shape or slope of the contact between the lever 3 and the inertial mass 6.

During this movement, the compression spring 11 is compressed. In addition, the inclined contact rotates the inertial system a few degrees back. The door is always closed here.

FIGS. 11A, 11B, 11C, 11D illustrate views of this same locking and unlocking mechanism after a first attempt to open the opening, after which the user releases the grip lever 2 of the handle for the first time

1.

When the user releases the handle 1 after the first attempt to open the door with a high force, the compression spring 11 pushes the inertial mass 6 in the direction F4 (opposite with respect to the direction F3) against the pawl 7. The inertial system, previously rotated a few degrees back, returns to a different position and engages the notches relative to the teeth. The inertial mass 6 is always in the blocking position and the door is always closed.

FIGS. 12A, 12B, 12C, 12D illustrate views of this same locking and unlocking mechanism 10 during a second movement of opening of the handle, after the user has attempted the first time to open the handle then to have released it.

When the outside user tries again to open the handle 1 for the second time, the shoulder 31 of the transmission lever 3, and in particular of the counterweight 30 ', comes into contact with the inertial mass 6, at its locking pin 61, and remains blocked (the door therefore does not open).

If the outside user tries to exert a greater force, the transmission lever 3 with the counterweight 30 'pushes the inertia system! in direction F3 thanks to the inclined shape of the contact between the contact surface 32 of the transmission lever 3 and the locking pin 61 of the inertial system.

During this movement, the compression spring 11 is compressed for the second time. The inclined shape of the contact surface 32 of the transmission lever 3 allows the inertial system to rotate a few degrees backwards. The door is still closed.

FIGS. 13A, 13B, 13C, 13D illustrate views of this same locking and unlocking mechanism after a second attempt to open the opening, after which the user releases the grip lever 2 of the handle a second time 1.

When the user releases the handle after the second attempt to open the door with a high force, the compression spring 9 pushes the inertial system in the direction F4 against the pawl 7. The inertial system, previously turned a few degrees backwards , then returns to the rest position because no more tooth 71 of the pawl 7 opposes the force of the return spring 9 tending to return the inertial mass 6 to its rest position. The handle is then free to be used by its user in its standard use.

Figures 14 and 15 illustrate views of a locking and unlocking mechanism 10 according to another embodiment.

This embodiment differs essentially from that illustrated in the previous figures in that the second axis A is horizontal and substantially perpendicular to the third axis of rotation B, the latter being parallel to the first axis of rotation Z.

Indeed, such a mechanism is particularly suitable for handles in the opening is implemented by a horizontal rotation of the gripping lever 2 (not visible in these figures).

The invention is described in the foregoing by way of example. It is understood that a person skilled in the art is able to carry out different variant embodiments of the invention without going beyond the ambit of the invention.

For example, the handle can be any type of vehicle handle, and preferably a flush handle called "flush". The handles called "Flush" are handles in the grip lever 2 is flush with the outer face 110 of the door 100, this type of handles being more and more present on vehicles for aesthetic reasons.

Furthermore, the figures illustrate an embodiment in which the actuation of the gripping lever 2 is a displacement of said gripping lever 2 from its rest position towards its control position. However, it may be otherwise, such as moving the grip lever in an opposite direction.

In the case of flush handles for example, the movable gripping lever between a first rest position in which the handle is flush with the external face 110 of the leaf 100, a second gripping position, in which the handle is inactive but in a so-called extended position to allow a user to grasp with his hand the gripping lever 2 and third control position for opening a lock of the opening.

In certain cases, for this type of handles, manual user support on the gripping lever makes it possible to mechanically trigger the movement of said gripping lever from its flush position to its gripping position (“push-push” type system ). During this manual support, the gripping lever moves towards the inside of the base 4. It is during this movement that the actuation of the unlocking mechanism can for example be considered.

Of course in this case, substantial modifications can be provided with respect to the illustrated embodiment.

For example in this case, it is possible to dispense with a ratchet mechanism. Indeed, the action of pushing the gripping lever 2 will cause in its travel directly the withdrawal of the shoulder 31 from the travel of the locking lug. The unlocking mechanism can always be activated by repeated actuation of the gripping lever, for example with several blocking pins succeeding one another in blocking the shoulder 31 during its rotation.

In this case also, if an electrical actuation is provided to actuate the handle, a declutching means is preferably installed so that this movement does not cause a forced rotation of the motor shaft.

Claims (10)

1. Handle (1) of an opening (100) of a motor vehicle (101) comprising: a gripping lever (2) movable in rotation between a rest position and a control position for the opening of a lock of the opening (100), - a transmission lever (3) mounted in a base (4) of the handle (1) arranged to be fixed to the opening (100), the transmission lever (3) being configured to be actuated by the gripping lever (2) and pivot between a rest position and an active position in which the transmission lever (3) actuates the opening of the lock, and a security system (5) mounted in the base (4), configured to prevent rotation of the transmission lever (3) in the event of an impact, the safety system (5) comprising at least one inertial mass (6) pivotally mounted between a rest position and an active position preventing rotation of the transmission lever (3 ), the handle (1) being characterized in that it comprises a locking mechanism (10) configured to block the inertial mass (6) when it reaches the active position, and an unlocking mechanism (10) configured to unlock the inertial mass (6) when activated by a actuation of the gripping lever (2). 2. Handle (1) according to claim 1, characterized in that the locking mechanism and the unlocking mechanism are formed by all or part of the same locking and unlocking mechanism (10). 3. Handle (1) according to claim 1 or 2, characterized in that the locking mechanism (10) is configured so that the actuation of the gripping lever (2), in the blocking position of the inertial mass (6 ), causes it to be released beyond a predetermined release force on the handle (1), this release force being greater than an average effort to open the handle (1). 4. Handle (1) according to any one of the preceding claims, characterized in that the unlocking mechanism (10) is activated by repeated actuation of the gripping lever (2) 5. Handle (1) according to any one of the preceding claims, characterized in that the actuation of the gripping lever (2) is a displacement of said gripping lever (2) from its rest position to its control position. 6. Handle (1) according to any one of the preceding claims, characterized in that the security system (5) comprises a locking lug (61) secured to the inertial mass (6), which cooperates with a shoulder (31 ) of the transmission lever (3) when the inertial mass! the (6) is in the active position, the shoulder (31) of the transmission lever (3) having a contact surface (32) configured so as to move the locking pin (61) forming a follower when the transmission lever (3) is pivoted, the inertial mass (6) being released from the locking mechanism (10) after a predetermined displacement of the inertial mass (6). 7. Handle (1) according to any one of the preceding claims, characterized in that the locking mechanism, preferably the locking and unlocking mechanism (10), is a ratchet system. 8. Handle (1) according to claims 6 and 7, characterized in that the locking mechanism, preferably the locking and unlocking mechanism (10), comprises a pawl (7) configured to cooperate with a toothed wheel (60 ), the toothed wheel (60) being integral with the inertial mass (6) and in that the displacement of the locking pin (61) forming a follower when the transmission lever (3) is pivoted allows the release of the mechanism locking (10) after a movement such that the toothed wheel (60) is released from its cooperation in engagement with the pawl (7). 9. Handle (1) according to any one of the preceding claims, characterized in that it comprises an elastic return means such as a return spring (9) for returning the inertial mass (6) to the rest position, said return spring (9) preferably being of the torsion spring type. 10. Handle (1) according to any one of claims 7 to 9, characterized in that the locking and unlocking mechanism (10), for example the ratchet system, is constrained by a return spring (11) such that a compression spring, so as to constrain and maintain the toothed wheel (60) of the inertial mass (6) against the pawl (7).