Shock-resistant motorized locking device

Abstract

A locking device includes a mobile locking member, movement of which can be prevented by a blocking member interacting with a motorized lever, where the motorized lever is capable of rotational movement about an axis with respect to the supporting structure, the centre of gravity of the lever lying on the axis, the lever being kept in a determined stable position and without rigid mechanical contact of the lever with the supporting structure apart from its axis of rotation.

Claims

1. An apparatus comprising a locking device, said locking device comprising a supporting structure, a mobile locking-member, a piston, a motorized lever, and an actuator, wherein the mobile locking member comprises a housing wherein the actuator comprises a magnet, a stator, and an air gap, wherein the piston comprises a head, wherein the piston prevents movement of the mobile locking-member by engaging the head in the housing, wherein the motorized lever interacts with the piston, wherein the motorized lever is capable of rotational movement about an axis that is stationary with respect to the supporting structure, wherein the motorized lever moves between a locking position and an unlocking position, wherein the locking position is a stable locking-position, wherein, in the locking position, the motorized lever prevents movement of the piston and disengagement of the head thereof from the housing, wherein, in the unlocking position, the motorized lever enables movement of the piston and the release of the locking member when the head is fully extended out of the housing, wherein a center of gravity of the lever is located on the axis, wherein the motorized lever is held stable in the locking position and without rigid mechanical contact between the motorized lever with the supporting structure apart from the connection of its axis of rotation with the supporting structure, wherein the actuator drives the motorized lever to rotate about the stationary axis, wherein the magnet is fixed to the motorized lever, wherein the stator is fixed to the supporting structure, wherein the stator comprises ferromagnetic parts and a coil wherein the coil is a magnetic-field generating coil that produces a magnetic field when energized, wherein the stator's ferromagnetic parts channel the magnetic field, wherein interaction of the magnetic field and the magnet fixed to the motorized lever couples the motorized lever and the stator, wherein as a result of the coupling between the motorized lever and the stator, the motorized lever is induced to rotate, wherein the air gap is between the motorized lever and the stator, wherein the air gap varies in response to the rotation of the motorized lever, wherein the air gap has a minimum width when the motorized lever is in the stable locking position, wherein the air gap has a maximum width when the motorized lever is in the unlocked position, and wherein, when the field-generating coil is no longer energized, the motorized lever remains subjected to a torque that tends to hold the motorized lever in the stable locking position in which the air gap has a minimum width, wherein said torque arises from interaction of said magnet and said ferromagnetic parts.

2. The apparatus of claim 1, wherein the stable locking-position is achieved without any power consumption.

3. The apparatus of claim 2, wherein the stable locking-position is achieved by the action of a magnetic force acting without any mechanical contact on the lever.

4. The apparatus of claim 3, wherein the actuator provides the magnetic force that maintains the stable position of the lever.

5. The apparatus of claim 2, further comprising a mechanical spring, wherein the stable locking-position is achieved at least in part by action of the mechanical spring.

6. An apparatus comprising a locking device, wherein the locking device comprises a supporting structure, a mobile locking bolt that is linearly moveable along an axis thereof between extended and retracted positions, a tapered piston that is vertically moveable from a blocking position to an unblocking position, wherein, as a result of being tapered, the tapered piston prevents the bolt from moving from the extended position to the retracted position when the tapered piston is in the blocking position, wherein the tapered piston moves in a direction that is angularly offset from the axis, an elongated lever rotatable about a pivot between a locking orientation aligned with the direction in which the tapered piston moves and an unlocking orientation angularly offset from the locking orientation, the lever being rotatable about a stationary axis, the stationary axis being stationary relative to the supporting structure, wherein a center of gravity of the elongated lever is at said stationary axis, a magnet on the elongated lever, and a structure that is located adjacent to the lever, and that, in operation, attracts the elongated lever toward one of the orientations, wherein the structure is a stationary and magnetizable structure that comprises a stator that comprises ferromagnetic parts and a coil that, when energized, generates a magnetic field, the ferromagnetic parts of the stator being configured to channel the magnetic field produced by the coil so that the magnetic field produced by the coil couples to the magnet that is on the elongated lever and thereby, as a result of the coupling, the magnetic field produced by the coil induces rotation of the elongated lever, wherein an air gap between the elongated lever and the stator has a width that varies as the elongated lever rotates about the stationary axis, wherein the width of the air gap varies between a minimum value, which is reached when the elongated lever is in a stable locking position, and a maximum value, which is reached when the elongated lever is in an unlocked position, wherein, when the coil is no longer energized, the motorized lever is subjected to a torque that tends to hold the motorized lever in an orientation that minimizes the width of the air gap, wherein said torque arises from interaction of said magnet and said ferromagnetic parts.

7. The apparatus of claim 6, wherein, with the exception of a surface of the pivot, all surfaces of the elongated lever are spaced away from all surfaces that are adjacent to the elongated lever when the elongated lever is in the locking orientation.

8. The apparatus of claim 6, wherein an end of the elongated lever is wider than a width of the lever at the pivot.

9. The apparatus of claim 6, wherein the magnetizable structure generates magnetism to attract the elongated lever toward the locking orientation, the magnetizable structure including a ferromagnetic material.

10. The apparatus of claim 6, wherein the elongated lever includes a magnet adjacent to the stator.

11. The apparatus of claim 6, wherein the stator is located on a line that is parallel to the axis of the bolt, and wherein the line extends along the elongated lever and runs through the pivot of the elongated lever.

12. An apparatus comprising a locking device, wherein the locking device comprises a supporting structure, an electromagnetically-movable locking bolt having a housing, a piston that is moveable between a first position and a second position, wherein in the first position the piston engages a head thereof the housing of the bolt and wherein in the second position the piston disengages the head thereof from the bolt, a lever that is rotatable about a pivot between locking and unlocking orientations, wherein the lever has a wide end and a narrow center, wherein the lever rotates about an axis that is stationary relative to the supporting structure, wherein the lever has a center of gravity that coincides with the axis that is stationary relative to the supporting structure, an end of the piston having a width less than a linear dimension between the wider ends of the lever when the lever is rotated to the unlocking orientation; and a stationary magnetizable structure that is located on an opposite side of the pivot from the bolt, the stationary magnetizable structure including a stator having ferromagnetic parts and a magnetic-field generating coil that, when energized, generates a magnetic field that is channeled by the ferromagnetic parts and couples to a magnet on the lever so as to induce rotation of the lever, the lever and the stator being separated by an air gap having a width that varies between a maximum and a minimum as the lever rotates, the minimum being reached when the lever is in a stable locking position and the maximum being reached when the lever is in an unlocking position, wherein, when the coil is no longer energized, the lever is subjected to a torque that tends to hold the lever in a position that minimizes the air gap, wherein said torque arises from interaction of said magnet and said ferromagnetic parts.

13. A locking device according to claim 12, wherein the pivot has surfaces, among which is a surface that is adjacent to the pivot, wherein, with the exception of a surface adjacent to the pivot, all the surfaces of the lever are spaced away from all surfaces that are adjacent to the lever when the lever is in the locking orientation.

14. The apparatus of claim 12, wherein: the bolt is linearly moveable when the piston is in the disengaged position, wherein, in operation, the magnetizable structure generates magnetism to attract the lever toward the locking orientation, and wherein the magnetizable structure comprises ferromagnetic material.

15. The apparatus of claim 12, further comprising a motorized actuator operable to rotate the lever, wherein a center of gravity of the lever is located at the pivot.

16. The apparatus of claim 1, wherein the torque varies as a function of an extent to which the motorized lever deviates from the stable locking position a torque is exerted that urges the motorized lever back to the stable locking position.

17. The apparatus of claim 1, wherein, after having been energized, when the field-generating coil is no longer energized, movement of the motorized lever away from the stable locking position gives rise to a torque that urges the motorized lever back to the stable locking position.

18. The apparatus of claim 6, wherein the tapered piston is vertically movable from a blocking position to an unblocking position.

Description

BRIEF DESCRIPTION OF THE FIGURES

(1) The relevance of the invention will be better understood when reading the following description of the various figures, which show various possible configurations:

(2) FIG. 1 is a perspective representation of a complete electromechanical lock device based on the use of an electric motor and a contactless stabilizing device according to a first embodiment.

(3) FIGS. 2a, 2b and 2c are detailed front views of the device of FIG. 1, shown in three different states.

(4) FIG. 3 is a representation of the invention according to a second embodiment of the actuating device, which has an intrinsic characteristic of stability without current provided by the actuator.

(5) FIGS. 4a, 4b and 4c are detailed front views of the device of FIG. 3 shown in three different states.

(6) FIG. 5 is a plot of the torque exerted on the locking lever according to the power supply to the actuator and to the position of the lever according to the embodiment shown in FIG. 3.

(7) FIG. 6 is a perspective view of a complete electromechanical lock device according to a third embodiment based on the use of an actuator of the vane solenoid type and of a stabilizer based on elastic springs.

(8) FIGS. 7a, 7b and 7c are detailed front views of 3 states of the structure shown in FIG. 6.

(9) FIGS. 8a and 8b are detailed front views of 2 states of an alternative structure shown in FIG. 6.

DETAILED DESCRIPTION

(10) The following description refers to a non-restrictive exemplary embodiment as a lock with a mobile bolt. But the invention is not limited to the embodiment of a lock and extends to any type of locking device comprising a mobile member which can be temporarily immobilized by means of a motorized member interacting with a motorized lever.

(11) The described exemplary embodiments are not restrictive and relate to a lock 1 comprising a supporting structure 3, and a bolt 9 mobile by translation with respect to the supporting structure 3, the movement of which can be blocked by the head of a piston 6 engaging in a housing 10. Such piston 6 is mobile in translation, in a direction perpendicular to the direction of movement of the bolt 9. A spring 16 urges the piston 6 at rest towards the bolt 9, so as to keep the piston head in the position where it is engaged in the housing 10. The piston head 6 has a truncated or conical shape, matching the shape of the housing 10, so that the movement of the bolt 9 pushes the piston 6 back, because of the transverse component (perpendicular to the axis of movement of the bolt 9) of the forces exerted by the inner edge of the housing 10 on the piston head 6.

(12) The lock further comprises a lever 5 which can move between a locking position where it prevents the movement of the piston 6, and thus the disengagement of the head thereof, and an unlocking position which enables the movement of the piston and the release of the bolt 9 when the piston head 6 is fully extended out of the housing 10. The aim of the invention is to prevent shocks exerted on the bolt 9 or any other accessible part of the lock from propagating to the lever 5 with enough energy to cause the untimely movement thereof from the locking position to another position where it would no longer provide the locking of the piston 6 movement.

(13) FIGS. 1, 2a, 2b and 2c show a motorized locking device 1 according to a first embodiment. Such lock mechanism comprises a rotating actuator 2, integral with the supporting structure 3, electrically controlled by a polyphase switched motor, a torque motor or still a proportional angular or variable reluctance actuator. The rotor of the actuator 2 is mechanically coupled to the locking lever 5, the design of which enables the latter to clear the passage of a third part (the piston 6 in the drawing) when it has completed the rotational movement generated by the supply of the actuator 2.

(14) The lever 5 has, in association with the rotor of the actuator 2 which it is attached to, a centre of gravity on its axis of rotation 7. According to this embodiment, the lever 5 is made of a ferromagnetic material. The lever 5 is thus sensitive to the magnetic field generated by a polarized (=magnetized) structure 8 integral with the supporting structure 3. The magnetic circuit is so designed that it generates a stable position of the lever in at least one position. Thus, when the actuator 2 is not energized, the rotor assembly is subjected to a magnetic attraction, via the lever 5, which tends to re-position the latter in the vertical stable position. Having several stable positions (locked and unlocked states) is also conceivable in other mechanisms.

(15) From left to right, FIGS. 2a, 2b and 2c show three operating states of a locking device using the first embodiment. FIG. 2a shows the locked state. The bolt 9 is shown in the extended position. A piston 6 having a linear stroke is engaged in the bolt 9 in high position under the action of the spring 16.

(16) It cannot go down because of the presence of the locking lever 5. The piston 6 can engage into the bolt 9 thanks to a housing 10 provided in the bolt 9. Thus, if a force is applied to the bolt 9 so as to make the latter translate, such force is transmitted to the piston 6 according to two components. A horizontal component supported by the supporting structure 3 and, on the other hand, a lower vertical component, transmitted to the locking lever 5. As the lever is in its vertical stable position, it transmits such force to the supporting structure, because of an elastic deformation of the axis which connects it to the motor, or of the support of the actuator 2. Thus, the piston 6 cannot be released from the bolt 9, and the lock is locked.

(17) FIG. 2b shows the lever 5 when driven in rotation by the actuator 2 supplied with electric current. Under the action of the torque created, which has a higher intensity than the magneto-static torque generated by the polarized structure 8 which tends to hold it in a stable vertical position, the lever 5 is pivoted.

(18) FIG. 2c shows the mechanism in the unlocked position. The bolt 9 is subjected to a force which tends to make it translate. Because of the respective shapes of the piston 6 and of the bolt 9, the piston 6 is driven in translation. Since the lever 5 has pivoted, the piston 6 can travel on to be completely disengaged from the bolt 9. The lock will then be in an unlocked state.

(19) FIGS. 3 and 4 show a second embodiment of a mechatronic locking device 1 according to the invention operated as described in the explanations of FIGS. 1, 2a, 2b and 2c. The difference relates to the locking lever 5 which is so designed as to provide the function of rotor to the actuator and the function of stability by magnetic interaction. The lever 5 is thus balanced and polarized by the addition of a magnet 11. A stator 12 fixed to the supporting structure 3 consists of ferromagnetic parts and is equipped with a magnetic field generating coil 13. When energizing the coil 13, the magnetic field produced is channelled by the ferromagnetic structure of the stator 12. The interaction with the magnetic field created by the magnet 11 of the lever 5 generates a couple between the lever 5 and the stator 11, which induces the rotation of the lever 5. The assembly is so designed that the air gap between the lever 5 and the stator 11 varies according to the rotation of the lever 5. A minimum air gap can thus be achieved when the lever 5 is in its stable position and a maximum air gap in the unlocked position thereof. In doing so, when the coil 13 is no longer energized, the lever 5 is subjected to a torque which tends to hold it in the stable position of the minimum air gap.

(20) In FIG. 4a, the device is shown in the locked position. The piston 6 is engaged in the bolt 9 and its stroke is hampered by the vertical position of the locking lever 5. In this position, the air gap between the locking lever 5 and the poles 14 of the stator 12 is minimum. As the coil 13 is not energized, the torque applied without contact between the lever 5 and the stator 12 is null in this position. The torque on the lever 5, based on its position and on the current flowing through the coil 13 surrounding the stator 12 is shown in FIG. 5.

(21) In FIG. 4b, the lever 5 is rotated when the coil 13 is energized. The air gap is then more important than when the lever 5 is vertical. The result is that, if the current in the coil is cancelled 13, a magneto-static torque (=with no current) will be created and will drive the lever 5 to the stable position of minimum air gap.

(22) Eventually, in FIG. 4c, the device is shown in an unlocked state. The lever 5 has been rotated from its vertical position, thus releasing the piston 6 which is then liable to go down under the action of a force exerted on the bolt 9.

(23) FIG. 5 shows the torques obtained on the axis of the locking lever of an actuator as shown in the descriptions of FIGS. 3, 4a, 4b and 4c. The vertical stable position with the minimum air gap corresponds to the 0 position. Because the air gap increases with the rotation of the lever 5, the torque without current in the coil 13 follows the central solid curve, which can be compared to a mechanical stiffness having a magnetic origin. The lowercrossesand uppersquarescurves are the torques obtained for opposite current polarities in the coil 13. Moving from the 0 locked position to the 30 unlocked position can be achieved by applying a >0 current in the coil 13.

(24) FIG. 6 shows an embodiment of the invention based on the use of a rotary actuator of the solenoid type as shown, for example, in the patent FR2834119. Such structure has no magnet, and may be doubled to increase the torque on the lever 5. When the coil 13 is energized, the magnetic flux generated is channelled by the stator 12, and the stator 12 is composed of two separate parts, and loops back through the ferromagnetic locking lever 5. In doing so, an attractive force is generated between the stator 12 and the lever 5. Since the actuator 2 is not polarized, a mechanical spring 15 is used here to ensure the stability of the lever 5 in vertical position. The mechanical spring 15 is advantageously attached to the lever 5, close to the axis of rotation, in order to dampen the transmission of the shock wave when the lock 1 is subjected to an external shock.

(25) FIGS. 7a, 7b and 7c show, in detail, the three distinct states of the solution presented in FIG. 6. In FIG. 7a, the lever 5 is held in a stable position without current by the resilient rigidity of the torsion spring. In FIG. 7b, energizing the coils 12 generates a torque on the locking lever 5 which pivots while compressing the torsion spring 15. In FIG. 7c, the lever 5 has travelled on its entire stroke, under the action of the magnetic field generated by the stator 12. The piston 6 can then slide and release the bolt 9.

(26) FIGS. 8a and 8b show an embodiment of the invention as shown in FIG. 6, with the difference that the mechanical spring 15 used is of the linear type (a torsion spring here). FIGS. 8a and 8b show the device in the locked and unlocked conditions, respectively.