WO2012076780A1 - Mechanical device for applying a mechanical force - Google Patents

Abstract

Mechanical device intended to apply a mechanical force, at least comprising: a means for guiding rotation; a control member (2) that can move relative to a fixed body (1) between at least one unengaged position and an engaged position; a driving means (3) coupled to the control member (2), having at least one axle (4) and able to move, at least in translation, in a predefined direction relative to the mechanical system between at least one rest position and a depressed position, depressed in response to said movement of the control member (2); an arm (51, 52) connected to said axle (4) and having a prominent end (511, 512) intended to apply the force and able to pivot about the axle (4) between an initial rotation position and a final rotation position, the movement of said driving means (3) simultaneously causing the arm (51, 52) to rotate in the same direction as the movement of said driving means and, via the guiding means, rotation of the arm (51, 52) about the axle; and elastic means that tend to return the driving means (3) to the rest position and the arm (51, 52) to the initial rotation position.

Description

 MECHANICAL DEVICE FOR APPLYING AN IMPULSION

MECHANICAL

Technical area

The invention relates to the field of mechanisms used for the transfer of mechanical energy. The invention relates in particular to a mechanical device allowing in particular the setting in motion of at least one element of the mechanical system, for example its setting in oscillation, in response to an external mechanical action, such as the support of a push button by a user.

The invention can in particular be implemented in an electric energy generator by piezoelectric effect, to trigger the oscillation of a beam associated with a piezoelectric element, when the user presses a control button. .

State of the art

An electric generator is a device comprising a mechanical system capable of producing electrical energy from another form of energy, and in particular from a mechanical energy. For example, this electrical energy may be consecutive to the deformation of piezoelectric elements or the variation of a magnetic field inside a solenoid.

For example, in an electric energy generator by piezoelectric effect, the mechanical energy received resulting in the deformation of piezoelectric elements, is converted into electrical energy. Indeed, a piezoelectric material is electrically polarized under the action of a mechanical stress. Thus, a deformation exerted on this piezoelectric material generates charges that can be measured electronically. Such a piezoelectric generator is for example described in the document WO 2010/007309, and includes in particular one or more vibrating blades, each having a free end that can oscillate under the effect of a mechanical pulse exerted by a mechanical device. Piezoelectric elements reported on the faces of the blades, deform under the effect of these oscillations, causing the appearance of electrical energy at the terminals of each of the piezoelectric elements. The electrical energy thus produced can be processed to adapt to the power supply of a load such as a radio module, a sensor or electronic components. Presentation of the invention

The present invention thus aims to provide a mechanical device for the quasi-point application of a force on at least one element of a mechanical system. Following the occasional application of this force, the mechanical system then reacts in a way that is unique to it, this reaction inducing, most often, the generation of electrical energy. Such a reaction may be for example an oscillation of this element around its rest position.

The invention aims in particular to provide a mechanical device capable of exerting a mechanical pulse of predetermined force and amplitude on this mechanical system, from a point action of a user on a control member. For example, the mechanical system may be a blade that has a piezoelectric element, or that carries a magnet coupled to a coil. The invention thus relates to a mechanical device for the application of a mechanical pulse which results in the application of a mechanical force on a mechanical system followed by almost instantaneous release of said mechanical system.

According to the invention, the mechanical device comprises at least:

 - a fixed body;

 rotational guiding means;

 a movable control member relative to the fixed body, between at least one position off actuation and an actuating position, and intended to be actuated, for example by a user or a user interface such as a rotary knob, a pressure roller , a pantograph;

 a body movable relative to the fixed body, comprising at least:

a driving means coupled to the control member, carrying at least one axis of rotation, and able to move at least in translation, in a predefined direction relative to the mechanical system, between at least one position of rest and a driving position in response to said displacement of the control member;

 an arm having an end mounted on said axis of rotation, and a protruding end for the application of mechanical force and said almost immediate release, and adapted to pivot about the axis of rotation between an initial rotational position and a final rotational position, the displacement of said drive means simultaneously causing the translation of the arm in the same direction as the displacement of said drive means and, through the guide means, the rotation of the arm about the axis of rotation; and

 elastic means adapted to return the drive means in the rest position and the arm in the initial rotational position, for example in the absence of actuation of the control member by the user. In other words, the invention proposes a mechanical device comprising at least one arm having a projecting portion intended for the application of a mechanical pulse of predetermined force and amplitude to the mechanical system.

This mechanical system is in particular capable of generating electrical energy in response to the mechanical pulse applied to it. For example, the mechanical system may comprise a magnet movable with respect to a coil, or a piezoelectric element attached to a flexible blade.

By mechanical impulse is meant a stress applied during a defined period of time, generally very short, followed by an instantaneous release of this state of stress. The arm is in particular moved in translation and in rotation by the displacement of the control member via the drive means and the rotating guide means. In one embodiment, the movement in translation makes it possible in particular to bring the protruding end of the arm of the mechanical system closer together, and the rotation makes it possible in particular to apply a mechanical pulse to this mechanical system so as to make this mechanical system react. a way of its own. In a particular case, the mechanical pulse can be applied to a system element mechanical, the application of this pulse causing the oscillation of this element around its rest position.

For example, the mechanical system may comprise at least one blade on which a piezoelectric body is attached. Thus, the application by the mechanical device of a mechanical pulse on a free end of this blade causes the oscillation of the blade around its rest position and therefore the deformation of the piezoelectric body attached to the blade, hence the production of electrical energy. In practice, the control member and the drive means can form a single piece.

This invention offers the advantage of allowing the application of a mechanical pulse of predetermined amplitude and force, independent of the characteristics of the action of the user on the control member.

For example, when the control member is a push button whose stroke is small, for example less than or equal to a few millimeters, a small actuation force, for example less than or equal to a few newtons, may suffice.

For example, the drive means may be associated with a user interface, other than the push button, such as a rotary knob, a switch, a pantograph. Advantageously, the rotational guiding means comprises a cam integral with the fixed body, in contact with the arm during at least part of an actuating phase during which the drive means moves from its rest position to its driving position, and capable of inducing the spacing of the arm from its initial rotational position during said actuation phase. In other words, the point of contact between the arm and the fixed part is movable and moved by the displacement of the drive means. In addition, the displacement of this point of contact along the arm causes the arm to move away from its initial rotational position during the actuation phase.

Advantageously, the mechanical device may further comprise a holding means adapted to hold the arm in its final rotational position, after the impulse has been made on the mechanical system, during part of a return phase during which the driving means evolves from its driving position to its rest position.

In other words, after the almost immediate release of the mechanical system, the return of the arm to its initial rotational position is delayed with respect to the return of the drive means to its rest position.

For example, the holding means may be a magnet secured to the drive means. The holding means may also be a complex shape, for example an excess thickness in the arm, the friction between this complex shape and the drive means inducing said holding of the arm.

Advantageously, the arm further comprises a portion, for example a pin, adapted to abut with a portion of the fixed body after the retraction of the drive means beyond a predetermined position, so as to release the arm of the holding means.

The elastic means may comprise at least:

 a first spring secured to at least the arm, and adapted to return the arm to the initial rotational position, for example in the absence of actuation of the control member by the user; and

a second spring secured to the fixed body and to the driving means or to the control member, and adapted to return the drive means to the rest position in the absence of actuation of the control member by the 'user. According to one embodiment, the mechanical device comprises two arms mounted mobile in rotation at least about said axis of rotation and forming a clamp, the two arms pivotally symmetrically from one another, and synchronously. According to this embodiment, each arm can be rotatably mounted about a distinct axis of rotation.

According to another embodiment, each arm further comprises a lug intended to rest on the mechanical system when the control member is in position off actuation. This tab allows in particular to maintain the arm in initial rotational position. In addition, this tab may be provided with means capable of absorbing vibrations and attenuating the noise resulting from the contacting of the tab with the mechanical system. This means is for example made of felt or rubber. The invention also relates to a device generating an electrical energy, comprising at least:

 a mechanical system capable of generating electrical energy in response to a mechanical pulse applied thereto;

 a mechanical device as described above for the application of the mechanical pulse to the mechanical system, in response to an action on the control member.

For example, the mechanical system may be a magnetic system capable of generating electrical energy by magnetic conversion, such as for example a magnet able to move in front of a coil.

The mechanical system may also be a piezoelectric system capable of generating electrical energy by a piezoelectric effect, such as for example a blade on which a piezoelectric body is attached, the mechanical pulse being applied to a free end of the blade. Advantageously, the generating device may further comprise electronic means for recovering and processing the energy generated by the mechanical system, able to generate an electrical voltage suitable for supplying a load.

The invention also relates to an electronic device incorporating a generator device as described above.

Brief description of the drawings

Other features and advantages of the invention will emerge clearly from the description which is given below, by way of indication and in no way limitative, with reference to the appended figures, in which:

 Figure 1 is a partial schematic representation of a mechanical device coupled to a mechanical system formed by two blades, according to one embodiment of the invention;

 Figure 2 is a side view of the portion A of the mechanical device of Figure 1;

 Figures 3 to 8 are partial schematic representations showing the operation of the mechanical device of Figure 1 in different successive phases; and

 Figure 9 is a partial schematic representation of the mechanical device according to another embodiment. Detailed presentation of a particular embodiment

FIG. 1 presents a device generating an electrical energy including:

 a mechanical system capable of generating electrical energy by a piezoelectric effect; and

a mechanical device for applying a mechanical pulse to the mechanical system. The mechanical system comprises in particular two blades on which piezoelectric elements are arranged. The realization of such a system is for example described in detail in the document WO 2010/007309. As illustrated in FIGS. 1 and 2, the mechanical device for the application of a mechanical pulse on each of these blades comprises in particular:

 a fixed body 1 (or frame) on which are hung each of the blades 11, 12 at their common end, the fixed body 1 may for example be the housing that accommodates the device;

 - A control member 2 movable relative to the fixed body 1, between at least one position off actuation and an actuating position, and intended to be actuated by a user. This control member 2 is for example a push button in slide-type connection relative to the fixed body 1. The mechanical device further comprises a drive means 3 coupled to the control member 2. This drive means 3 for example consists of a block 30 secured to the control member 2 by means of at least one rigid axis 31. Preferably, the block 30 is secured to the control member 2 by means of two rigid axes ( a single rigid axis 31 is visible in the figures). Thus, this drive means 3 moves in translation towards the blades 11, 12 between a rest position and a driving position in response to the displacement of the control member 2. For example, in the particular case of a push button, when the user presses the button, the drive means 3 advance towards the blades 11, 12, and when the user releases the button, the drive means 3 moves back. This decline can in particular be achieved through elastic means which will be explained in more detail below.

The mechanical device further comprises arms 51, 52 forming a clamp. Each arm 51, 52 is mounted on a separate axis of rotation 4, and each axis of rotation 4 is integral with the block 30 (in the figures, only the axis of rotation 4 on which the arm 51 is mounted is visible). More specifically, each arm 51, 52 has an end 510, 520 mounted on the corresponding axis of rotation 4, and a protruding end 511, 521 for the application of a mechanical pulse of predetermined force and amplitude on the free end of one of the blades 11, 12, in response to actuation of the control member 2, so as to cause the blades 11, 12 to oscillate. Before the application of a mechanical pulse, the protruding end 510, 520 of each arm is intended in particular to be positioned in the space between the two blades 11, 12. The mechanical pulse consists in particular in constraining the blades 11, 12 for a very short period of time by the application of a force and instantaneously release the blades 11, 12 of this state constraint by almost immediate ejection of these protruding ends out of said space. Each arm 51, 52 is furthermore capable of pivoting about the corresponding axis of rotation 4 between an initial rotational position and a final rotational position, the arms 51, 52 pivoting symmetrically from each other and from each other. synchronously around a rotation guiding means, such as a guide cam 6, which will be described below. The opening of the clamp is performed by moving the arms 51, 52 from their initial rotational position to their final rotational position.

In addition, and especially in the absence of actuation of the control member 2, each arm 51, 52 rests on the guide cam 6 integral with the fixed body 1. This positioning is due in particular to the return function performed by the elastic means, the cam 6 then acting as a stop for the arms 51, 52. This cam 6 is intended to remain in contact with each of the arms 51, 52 during at least part of the displacement of the drive means 3 in direction of the blades 11, 12, and to induce the spacing of the arms 51, 52 from their initial position of rotation.

In another embodiment, in the absence of actuation of the control member 2, each arm 51, 52 rests on one another. The displacement of the drive means 3 allowing each arm 51, 52 to come into contact with the cam 6 during at least part of the displacement of the drive means 3 in the direction of the blades 11, 12, and thus to induce the spacing the arms 51, 52 from their initial position of rotation.

In another embodiment illustrated in FIG. 9, in the absence of actuation of the control member 2, each arm 51, 52 comprises a tab 512, 522 intended to come to rest on one of the faces of a 11, 12. As illustrated in Figure 9, the lug 512 of the arm 51 is supported on the underside of the blade 11, and the lug 522 of the arm 52 is supported on the upper face of the blade 12. in other words, the blades 11 and 12 are positioned between the legs 512 and 522. This solution allows in particular to avoid any oscillation of the blades in the absence of actuation of the control member. In this solution, during the actuation of the control member, the rotation of the arms makes it possible initially to release the blades from the legs, and in a second step the application of the pulse by the prominent ends of the arms on these blades. Each leg may further be provided with means for absorbing vibrations and for reducing noise, for example felt or rubber.

Whatever the embodiment, the displacement of the control member 2 induces the displacement of the drive means 3, simultaneously causing the movement of the arms 51, 52 in the same direction as the displacement of the drive means and, by means of the guiding cam 6, the rotation of each arm 51, 52 around the associated axis of rotation 4.

Thus, during an actuation phase during which the control member 2 is actuated and moves from its position out of actuation to its actuated position, the drive means 3 advance in translation towards the blades 11, 12, simultaneously causing the advancement of the arms 51, 52 in the direction of the blades 11, 12 and the spacing of the arms 51, 52 from their initial rotational position through the guide cam 6.

On the one hand, the translational movement of the gripper induced by the advancement of the drive means 2 in the direction of the blades makes it possible to place the protruding end of each arm 51, 52 between the blades 11, 12. on the other hand, the rotational movement of the arms 51, 52 allows each of the protruding ends 511, 521 to approach one of the free ends and to apply a mechanical pulse on this free end.

A holding means 7, for example a set of magnets secured to the block 30 of the drive means 3, keeps each arm 51, 52 in its final rotational position, after the almost immediate pulse on the free ends. This maintenance takes place during part of a release phase during which the user releases the control member 2, causing the drive means 3 to return to its rest position. Thus, because of this holding means 7, the return of the arms to their initial rotational position is delayed with respect to the return of the drive means to its rest position. In another embodiment, the holding of the arms can be achieved by friction of a portion of each arm on a portion of the drive means.

In order to release each arm 51, 52 of the holding means 7, each arm 51, 52 is provided with a lug 53 (only visible in FIGS. 1 and 7 for the sake of clarity) adapted to abut with a portion 10 fixed body 1 after the retraction of the drive means 3 beyond a predetermined position.

The mechanical device further comprises elastic means for returning the drive means 3 to the rest position and the arms 51, 52 to the initial rotational position, in the absence of actuation of the control member 2 by the user.

These elastic means can in particular be constituted by:

 a torsion spring 81 for each of the arms 51, 52, adapted to bring the arm 51, 52 corresponding to the initial rotational position. Each torsion spring being secured to the block 30 of the drive means 3 and having a branch in contact with the drive means 3 and another branch in contact with the arm 51, 52 corresponding; and

 a tension spring 82 secured to the drive means 3 and the fixed body 1, and adapted to return the drive means 3 in the rest position in the absence of actuation of the control member 2 by the user .

The detailed operation of the mechanical device presented above for the occasional application of a force on the free end mechanism of each blade, is described hereinafter with reference to FIGS. 3 to 8.

FIG. 3 illustrates the position of the elements of the mechanical device as well as that of the blades 11, 12, in the initial state, that is to say in the absence of any prior actuation of the control member 2. L control member 2, here a push button, is in position out of operation identified by the dashed line referenced Pl. The arms 51 and 52 forming a clamp rest on the cam 6 and are in the initial rotational position. These positions are maintained by the torsion spring 81 and the tension spring 82. The actuation phase resulting from the actuation of the control member 2 by the user comprises two phases: the approximation phase illustrated in FIG. 4 and the constraint phase illustrated in FIG.

During the approach phase (FIG. 4), the user actuates the control member 2, here by pressing the push button, conferring a displacement of the push member from its position out of the actuation PI to its actuated position. represented by the dotted line and referenced P2. This displacement of the control member 2 causes the drive means 3 to advance and the clamp towards the blades

11 and 12. Simultaneously with this translation, the clamp opens via the guide cam 6, that is to say that each arm 51, 52 moves away from its initial rotational position and the protruding end 521, 522 approaches one of the blades. At the end of this approach phase, the control member 2 has made part of its total travel, the protruding ends 511, 512 are flush with the free ends of the blades 11, 12.

15 blades 11, 12 are not yet stressed, and the arms 51, 52 are still in contact with the cam 6.

During the constraint phase (FIG. 5), the control member 2 performs the remainder of its stroke, which causes the arms 51, 52 to advance and rotate towards their final position of rotation, and therefore the application a mechanical impulse by the arms on the blades 11, 12. This mechanical impulse results in the application of a stress on the blades and an almost immediate release of the blades 11, 12. This almost immediate release occurs by ejecting the protruding ends 511, 521 out of the space between the blades 11, 12. The blades 11, 12 then oscillate freely around their rest position.

At the end of this constraint phase, and especially after the application of the pulse, the control member 2 has finished its stroke and is in its operating position P2. In addition, the blades 11, 12 oscillate, the clamp is open at most 30 and held in this position by means of the holding means 7, here a magnet, for each arm, secured to the block 30 of the drive means 3 . FIGS. 6 to 8 illustrate the return phase during which the user releases the control member 2. During this return phase, the tension spring 82 brings back the drive means 3 and the control member 2 in the rest position and in the off position in the absence of actuation of the control member by the user.

This return phase takes place in two phases: a holding phase (Figures 6 and 7) and a detachment phase (Figure 8). During the holding phase (FIG. 6), each arm 51, 52 is held in its final rotational position by the magnets. The control member 2 moves from its operating position P2 to its off position P1. As a result, the driving means 3 and the gripper move back and away from the blades 11, 12. At the end of this during the holding phase, the control member 2 has made part of its return stroke under the action of the tension spring 82, the clamp is held in the open position, and the lug 53 (FIG. 7) of each arm 51 , 52 reaches a stop on a portion 10 of the fixed body 1.

During the detachment phase (FIG. 8), the control member continues its travel towards its position excluding actuation PI, thus releasing the arms 51, 52 of the holding means 7. Each arm 51, 52 is then brought back to its position of initial rotation by torsion springs 81.

At the end of this separation phase, all the elements are found in the initial state (Figure 3).

The operation of the mechanical device thus carries out a cycle comprising four phases:

 a phase of approximation to bring the pliers closer to the blades;

a constraint phase for applying a mechanical impulse to the blades; a maintenance phase, after pulse, to postpone the return of the arms in the initial rotational position relative to the return of the drive means; and a detachment phase to release the holding arms so as to bring them back to the initial rotational position, the set of moving elements of the mechanical device then being ready for a new cycle. Of course, the mechanical device may comprise a single arm in the case in particular where a single blade or any other system that would be associated with the invention should be constrained.

The mechanical device of the invention thus offers the possibility of applying a mechanical pulse of predetermined amplitude and force, with the aid of a single pressure of the user's finger on a push button.

In addition, the quality of the mechanical pulse is independent of the speed of action on the button. In other words, even if the user presses very gently, the pulse will be frank, and the energy recovered important.

In other words, the structure of the mechanical device makes it possible to release the blades almost immediately from any mechanical stress, thus offering good oscillation of the blades, and therefore a high efficiency for the conversion of mechanical energy into electrical power.

Moreover, once the pulse generated, the mobile elements of the mechanical device automatically return to the initial position, ready to respond to a new actuation of the control member.

The delayed return of the arms to their final rotational position allows the arm not to fall on the moving blades so as not to reduce the electrical energy that can generate the piezoelectric elements. In addition, this deferred return allows the arm to return to the initial rotational position without being in contact with the blades, which reduces the restoring forces to a minimum.

The point of contact between the arm and the cam is movable during the displacement of the control member, and for a constant actuating speed of the control member, there is an increase of the lever arm between the axis of rotation and the cam. The instantaneous speed of the protruding end of the arm is therefore increasing throughout the actuation of the control member, which allows to obtain a speed of relaxation of the blade by the high arm, and therefore a good quality d mechanical impulse.

Finally, the mechanical device can be compact and requires only a few mechanical elements. This mechanical device can be produced cheaply and have a smaller footprint. Of course, the mechanical device can be implemented for mechanical systems of the piezoelectric type, but also for other types of mechanical systems capable of converting mechanical energy into electrical energy, for example a mechanical system exploiting the effects of the variation of the magnetic field.

Claims

Mechanical device for the application of a mechanical pulse on a mechanical system, characterized in that it comprises at least:

 - a fixed body (1);

 rotational guiding means;

 a control member (2) movable relative to the fixed body (1), between at least one position off actuation and an actuating position, and intended to be actuated;

 a body movable relative to the fixed body (1), comprising at least:

 a drive means (3) coupled to the control member (2), carrying at least one axis of rotation (4), and adapted to move at least in translation in a predefined direction relative to the mechanical system between at least one rest position and a driving position in response to said displacement of the control member (2);

 an arm (51, 52) having an end (510, 520) mounted on said axis of rotation (4), and a protruding end (511, 512) for application of the mechanical pulse, and pivotable about of the axis of rotation (4) between an initial rotational position and a final rotational position, the displacement of said drive means (3) simultaneously causing translation of the arm (51, 52) in the same direction as the displacement said drive means and, through the guide means, rotating the arm (51, 52) about the axis of rotation; and

 resilient means adapted to return the drive means (3) to the rest position and the arm (51, 52) to the initial rotational position.

2. Mechanical device according to claim 1, characterized in that the rotation guiding means comprises a guide cam (6) integral with the fixed body (1), in contact with the arm (51, 52) during at least a part an actuating phase during which the drive means (3) moves from its rest position to its driving position, and adapted to induce the spacing of the arm (51, 52) from its position initial rotation during said actuation phase.

3. Mechanical device according to one of claims 1 or 2, characterized in that it further comprises a holding means (7) adapted to maintain the arm (51, 52) in its final rotational position, after the embodiment the pulse on the mechanical system during a part of a return phase during which the drive means (3) moves from its driving position to its rest position.

4. Mechanical device according to claim 3, characterized in that the holding means (7) is a magnet secured to the drive means (3) or a complex shape, at the arm, the friction between this complex shape and the driving means inducing said holding of the arm.

5. Mechanical device according to one of claims 1 to 4, characterized in that the arm (51, 52) further comprises a portion adapted to abut with a portion (10) of the fixed body (1) after the recoil driving means (3) beyond a predetermined position, so as to release the arm (51, 52) of the holding means (7).

6. Mechanical device according to one of claims 1 to 5, characterized in that the elastic means comprise at least:

 a first spring secured to at least the arm (51, 52) adapted to return the arm (51, 52) to the initial rotational position; and

 a second spring secured to the fixed body (1) and to the drive means (3) or to the control member (2), and able to return the drive means (3) to the rest position in the absence actuating the control member.

7. Mechanical device according to one of claims 1 to 6, characterized in that it comprises two arms mounted movable in rotation about at least one axis of rotation and forming a clamp, the two arms pivotally symmetrically one of the other, and synchronously.

8. Mechanical device according to one of claims 1 to 7, characterized in that each arm (51, 52) further comprises a tab (512, 522) intended to rest on the mechanical system when the control member (2 ) is in the off position.

9. Device generating an electrical energy comprising at least:

 a mechanical system capable of generating electrical energy in response to a mechanical pulse applied thereto;

 a mechanical device according to one of claims 1 to 8, for the application of a mechanical pulse on said mechanical system, in response to an action on the control member (2).

10. Generator device according to claim 9, characterized in that it further comprises electronic means for recovery and treatment of the energy generated by the mechanical system, able to generate an electrical voltage suitable for feeding a power supply. charge.

11. Electronic device incorporating a generating device according to one of claims 9 or 10.