JP4671762B2 - Electric steering lock device - Google Patents

Description

  The present invention relates to an electric steering lock device for locking a steering of an automobile or the like.

  Conventionally, a steering lock device used for locking a steering of an automobile or the like for the purpose of preventing theft is known. Generally, in a steering lock device, an engagement recess is provided on the outer periphery of a steering shaft that rotates in response to a steering operation, and a lock bolt enters and engages with the engagement recess to rotate the steering shaft. The steering is locked and the steering is locked. On the other hand, the lock bolt is released from the engaging recess and released, so that the rotation restriction of the steering shaft is released and the steering is unlocked. Yes.

  In the steering lock device, an electric steering is provided with an electric motor that provides a driving force for moving the lock bolt between a lock position engaged with the steering shaft and an unlock position engaged with and unlocked from the steering shaft. There is a locking device. For example, in the electric steering lock device disclosed in Patent Document 1 below, the lock bolt moves between the lock position and the unlock position in conjunction with the rotational movement of the cam member that is operated by the electric motor. .

JP 2002-205622 A

  However, in the electric steering lock device disclosed in Patent Document 1, the cam member is arranged so as to rotate in the movement direction of the lock bolt. There is a problem that the size is increased and the electric steering lock device itself is also enlarged.

In general, the electric steering lock device has the following problems.
(1) When the lock bolt moves to the lock position, if the tip of the lock bolt does not coincide with the engagement recess of the steering shaft, the lock bolt cannot be moved to the lock position.
(2) When pulling out the lock bolt from the engaging recess, if the inner surface of the engaging recess is in pressure contact with the lock bolt because of the stationary torque applied to the steering shaft, the lock bolt is pulled out. Absent.

Therefore, in order to solve the above problem, the present invention locks the steering or moves the lock bolt with the driving force of the electric motor to engage or disengage the movable member interlocked with the steering operation. In the electric steering lock device designed to unlock,
A cam groove that is inclined with respect to the circumferential direction is formed on the outer peripheral surface of the columnar portion of the lock bolt, a cylindrical rotating body that is rotationally driven by the electric motor is provided, and the columnar portion of the lock bolt is It is arranged so as to be movable in the axial direction inside the rotating body, and the lock bolt is moved by moving the cam follower held in the holding portion of the rotating body in the cam groove,
Provided with a biasing member which biases the locking bolt to the movable member side, the holding portion of the rotating body, extending in the direction in which the locking bolt is moved, and the locking bolt during the locking operation of the locking bolt When the front end does not coincide with the engagement recess of the movable member, the cam follower is a vertical groove formed so as to move backward ,
The cam follower moves along the cam groove while being held by the cam groove and the holding portion by the rotational drive of the rotating body.

According to this configuration, the lock bolt is operated by the rotating body that rotates in a direction perpendicular to the moving direction of the lock bolt, and the lock bolt is disposed inside the rotating body, so that the electric steering lock device is downsized. can do. In addition, since the cam groove is formed on the outer peripheral surface of the lock bolt, it is easy to form the cam groove, and a plurality of cam grooves or one long cam groove can be formed in a shape that does not cross each other. It becomes possible.
Further, when the tip of the lock bolt has performed a locking operation when no match the engaging concave portion of the movable member, the locking bolt is not able to move to the lock position engaging with the engagement recessed portion of the movable member Instead, the cam follower moves to the opposite side of the movable member along the longitudinal groove. When the leading end of the lock bolt is coincident with the engagement concave portion, the lock bolt by the biasing force of the biasing member moves to said locked position. Therefore, even when the lock bolt stops during the locking operation, the electric motor is not overloaded, and the lock bolt can be moved to the lock position without operating the electric motor again. .

  In the electric steering lock device of the present invention, two cam grooves and two cam followers may be provided with a shift of approximately 180 degrees.

If two cam grooves and two cam followers are provided in this way, the lock bolt can be operated without rattling compared to the case of one cam groove and one cam follower.
Further, when the two cam followers are arranged at positions shifted from each other with respect to the axial direction of the rotating body, the columnar portion of the rotating body and the lock bolt in which the cam groove is formed becomes longer in the axial direction. For this reason, the electric steering lock device is increased in size, but if the two cam followers are provided on the same plane perpendicular to the axial direction of the rotating body, the columnar portions of the rotating body and the lock bolt can be shortened. Thus, the electric steering lock device can be reduced in size.

  In the electric steering lock device of the present invention, the inclination angle of the cam groove on the rear end side of the lock bolt may be a gentle inclination, and the inclination angle of the cam groove on the front end side of the lock bolt may be a steep inclination.

  Thus, by changing the inclination angle of the cam groove in the middle, it is possible to increase the pull-out load when moving the lock bolt to the unlock position, and to speed up the operation of the lock bolt after it is pulled out. . Since the pull-out load can be increased in this way, the lock bolt can be reliably pulled out even when a stationary torque is applied to the steering shaft and the inner surface of the engaging recess of the steering shaft is in pressure contact with the tip of the lock bolt. . In addition, the reduction gear for increasing the pulling load can be eliminated and the motor can be reduced in size, thereby reducing the number of parts and the size of the entire electric steering lock device. Furthermore, after pulling out, the operation time of the motor can be shortened and the power consumption can be reduced by speeding up the operation of the lock bolt.

  In the electric steering lock device of the present invention, the cam follower may be a spherical ball member.

  If the lock bolt is operated through the spherical ball member in this way, it is possible to prevent the cam groove from being worn and abnormal noise and to reduce the resistance when the cam follower moves in the cam groove. Become.

In the electric steering lock device of the present invention, the cam follower may be a roller rotatably held by the holding portion of the rotating body .

According to this configuration, since the rotatable roller moves in the cam groove of the lock bolt, the loss of driving force due to friction is reduced compared to the case where the ball member as the cam follower slides in the cam groove. Can be reduced. As a result, the gear diameters of the motor and the rotating body can be reduced, and as a result, the electric steering lock device can be further reduced in size .

  As described above, according to the electric steering lock device of the present invention, the electric steering lock device can be reduced in size, restarted to the lock position after the lock bolt has stopped halfway, and the stationary torque can be reduced. The lock bolt can be pulled out when it is on.

Embodiments of the present invention will be described below with reference to the accompanying drawings.
FIG. 1 is a plan view of an electric steering lock device 10 according to a first embodiment of the present invention, and FIG. 2 is a side sectional view of the electric steering lock device 10 in a locked state. In FIG. 2 (the same applies to FIGS. 4 and 5), the left side is “front” and the right side is “rear” for convenience.

  The electric steering lock device 10 includes a case 14 that is closed by a cover 12. An electric motor 16 is fixed in the case 14. The electric motor 16 is electrically connected to a terminal 20 fixed to the printed circuit board 18, and is fed by a control unit (not shown) through the printed circuit board 18 and the terminal 20 from a connector 22 protruding from the side surface of the case 14. Therefore, it is driven forward or reverse. A worm 24 is attached to the rotating shaft 17 of the electric motor 16.

  Further, a cylindrical rotating body 26 is provided in the case 14. The rotating body 26 is held at a predetermined position by the cover 12 and the case 14 while being rotatable but not movable in the front-rear direction. A worm gear 28 is formed on the outer periphery of the rotating body 26. The worm gear 28 meshes with the worm 24. Thereby, the rotating body 26 is rotationally driven by the electric motor 16.

  Two longitudinal grooves 30 are formed in the inner peripheral portion of the rotating body 26 at positions shifted by approximately 180 degrees. The longitudinal groove 30 extends along the axial direction of the rotating body 26 (a direction coinciding with the movement direction of a lock bolt described later). Further, the vertical groove 30 has a substantially semicircular cross section, and constitutes a holding portion for holding two cam followers 32 each made of a spherical ball member. Here, the two cam followers 32 are provided on the same plane perpendicular to the axial direction of the rotating body 26. The cam follower 32 is not necessarily limited to a spherical ball member, and may be a member having another shape.

  A concave portion 34 that is recessed over a predetermined angular range is formed adjacent to the worm gear 28 on the outer peripheral portion of the rotating body 26, and both ends in the circumferential direction of the concave portion 34 become switch step portions 36 and 38. ing. The detection levers of the first detection switch 40 and the second detection switch 42 for detecting the rotation position of the rotary body 26 are in contact with the outer peripheral portion of the rotary body 26 where the recess 34 is formed. As shown in FIG. 1, when the electric steering lock device 10 is in the locked state, the first detection switch 40 is in the on state, and the second detection switch 42 is in the off state because the detection lever has fallen into the recess 34. It has become.

  Inside the rotator 26, a lock bolt 44 is disposed so as to be movable in the axial direction of the rotator 26. The lock bolt 44 includes a columnar portion 46 located in the rotating body 26 and a rod-shaped portion 48 having a substantially rectangular cross section extending from the columnar portion 46. When the electric steering lock device 10 is in the locked state, as shown in FIG. 2, the tip of the rod-like portion 48 of the lock bolt 44 protruding outward from the cover 12 enters the engagement recess 4 of the steering shaft (movable member) 2. Thus, the steering shaft 2 is restricted from rotating. At this time, the lock bolt 44 is in the locked position.

  In the present embodiment, the movable member that rotates in response to a steering operation (not shown) is described as the steering shaft 2. However, the movable member is not limited to the steering shaft 2, and is linked to the steering operation. Another member may be used.

  Two cam grooves 50 that are inclined with respect to the circumferential direction of the cylindrical portion 46 are formed on the outer peripheral surface of the cylindrical portion 46 of the lock bolt 44. The cross section of the cam groove 50 has a substantially radial shape, and the two cam followers 32 are respectively held in a state of being fitted into the vertical groove 30 and the cam groove 50 of the rotating body 32.

  FIG. 3 shows a developed view of the outer peripheral surface of the cylindrical portion 46, in which the equally spaced vertical lines are angle lines every 10 degrees, and the upper side in the figure is the tip side of the lock bolt 44 (ie, the steering shaft). The lower side in the figure corresponds to the rear end side of the lock bolt 44. As shown in FIG. 3, one cam groove 50 includes inclined portions 52 and 54 that are inclined with respect to the circumferential direction (left and right direction in FIG. 3) of the cylindrical portion 46 of the lock bolt 44, and the inclined portions 52 and 54. Extending portions 56 and 58 extending in the circumferential direction of the cylindrical portion 46 from both ends of the cylindrical portion 46, respectively.

  The inclined parts 52 and 54 are located on the rear end side of the lock bolt 44 and have a gentle inclination part 52 with a gentle inclination angle, and on the front end side of the lock bolt 44 and with a steep inclination part 54 with a steep inclination angle. It is made up of.

  The extending portions 56 and 58 cause the electric motor 16 and the rotating body 26 to rotate inertially even when the driving of the electric motor 16 is stopped when the cam follower 32 comes to the motor stop positions A and B shown in the drawing. This is to allow the cam follower 32 to enter the extending portions 56 and 58 when it does not stop immediately. This prevents a sudden stop of the electric motor 16 and prevents an overload on the electric motor 16. At the same time, the motor stop position can be set within a certain range including an error. Since the extended portions 56 and 58 extend in the circumferential direction of the cylindrical portion 46, the lock bolt 44 does not move even if the cam follower 32 moves into the extended portions 56 and 58.

  The other cam groove 50 has the same shape, but is formed at a position shifted from the one cam groove 50 by approximately 180 degrees. As a result, the two cam grooves 50 have portions that overlap with each other when viewed in the axial direction of the cylindrical portion 46, but are formed so as not to cross each other.

  In the present embodiment, providing two cam grooves 50 and two cam followers 32 has an effect of preventing rattling when the lock bolt 44 is operated, as will be described later, as compared to the case where each one is provided. Even if there is only one cam groove 50 and one cam follower 32, the lock bolt 44 can be operated. In this case, the cam groove 50 may be formed as one long groove extending in a spiral shape so as not to intersect. Good.

  On the outer peripheral portion of the rear end of the lock bolt 44, two engagement convex portions 60 are provided at positions shifted by 180 degrees. These engaging convex portions 60 are respectively engaged with two engaging groove portions 62 formed on the inner surface of the case 14 so as to be slidable. As a result, the lock bolt 44 is allowed to move in the front-rear direction, but cannot be rotated.

  A spring 64 as an urging member is disposed between the rear end of the lock bolt 44 and the case 14. The lock bolt 44 is urged toward the steering shaft 2 by the spring 64.

  Next, the operation of the electric steering lock device 10 having the above configuration will be described.

  As shown in FIGS. 1 and 2, when the electric steering lock device 10 is in the locked state, the electric motor 16 is driven forward so that the rotating body 26 is unlocked (ie, counterclockwise) as shown in FIG. ) Begin to rotate. As the rotation starts, the detection lever of the second detection switch 42 rides on the switch step 38 of the rotating body 26, so that the second detection switch 42 is turned on.

  When the rotating body 26 starts to rotate in this way, the cam follower 32 located in the vicinity of the motor stop position A in FIG. 3 moves while sliding or rotating in the cam groove 50, but the cam follower 32 is moved to the end of the vertical groove 30. The lock bolt 44 begins to move rearward due to the rotation of the rotating body 26 because it is located in the section and cannot move forward.

  When the cam follower 32 moves along the gently inclined portion 52 of the cam groove 50, the lock bolt 44 retracts relatively slowly from the lock position. As a result, the pulling-out load when the tip of the lock bolt 44 is pulled out from the engaging recess 4 of the steering shaft 2 can be increased, so that a stationary torque is applied to the steering shaft 2 so that the inner surface of the engaging recess 4 is The lock bolt 44 can be reliably pulled out even in a state where it is in pressure contact with the tip of the lock bolt 44. Further, the reduction gear for increasing the pulling load can be eliminated, and the electric motor 16 can be miniaturized, thereby reducing the number of parts and the electric steering lock device 10 as a whole.

  Subsequently, when the cam follower 32 moves to the motor stop position B along the steeply inclined portion 54 of the cam groove 50 according to the rotation of the rotating body 26, the lock bolt 44 moves backward relatively quickly. As described above, since the operating time of the motor can be shortened by speeding up the operation of the lock bolt 44 after the tip is pulled out from the engaging recess 4 of the steering shaft 2, the motor of the electric steering lock device 10 is operated. The responsiveness of the entire system including the control unit can be increased, and the power consumption can be reduced. In addition, for example, the time until the engine is started after unlocking the steering can be shortened, and the convenience for the user can be improved.

  When the rotating body 26 rotates approximately 180 degrees, the detection lever of the first detection switch 40 passes over the switch step 36 of the rotating body 26 and falls into the recess 34, whereby the first detection switch 40 is turned off. The forward drive of the electric motor 16 is stopped in response to this off signal, but the cam follower 32 slightly enters the extended portion 58 of the cam groove 50 and stops due to the inertial rotation of the electric motor 16 and the rotating body 26. At this time, as shown in FIG. 4, the lock bolt 44 is retracted to the unlock position where the tip is retracted into the cover 12.

  Thus, when the lock bolt 44 moves from the lock position to the unlock position, the engagement of the tip of the lock bolt 44 with the engagement recess 4 of the steering shaft 2 is released, and the rotation restriction of the steering shaft 2 is restricted. It is released and the steering is unlocked.

  Conversely, in order to put the electric steering lock device 10 in the locked state, the electric motor 16 is driven in reverse until the second detection switch 42 is turned off as shown in FIG. As a result, the rotating body 26 rotates approximately 180 degrees in the locking direction (ie, clockwise direction) shown in FIG. 1, and the rotation of the rotating body 26 moves the cam follower 32 along the cam groove 50 to the motor stop position A. As the cam follower 32 moves in this manner, the lock bolt 44 advances from the unlock position to the lock position shown in FIG. 2 by the biasing force of the spring 64. As a result, the front end of the lock bolt 44 enters and engages with the engagement recess 44 of the steering shaft 2, and the steering shaft 2 is restricted from rotating to lock the steering.

  As described above, according to the electric steering lock device 10 of the present embodiment, the lock bolt 44 is operated by the rotating body 26 that rotates in the direction perpendicular to the moving direction of the lock bolt 44, and Since the lock bolt 44 is disposed, the electric steering lock device 10 can be reduced in size. Further, since the cam groove 50 is formed on the outer peripheral surface of the lock bolt 44, the cam groove 50 can be easily formed, and the two cam grooves 50 or one long cam groove 50 is formed so as not to cross each other. Can be formed.

  In addition, since two cam grooves 50 and two cam followers 32 are provided, the lock bolt 44 can be operated without rattling compared to the case where one cam groove 50 and one cam follower 32 are provided.

  Further, when the two cam followers 32 are arranged at positions shifted from each other with respect to the axial direction of the rotating body 26, the columnar portion 46 of the lock bolt 44 in which the rotating body 26 and the cam groove 50 are formed by the shift amount. However, since the two cam followers 32 are provided on the same plane perpendicular to the axial direction of the rotating body 26, the rotating body 26 is increased. In addition, the cylindrical portion 46 of the lock bolt 44 can be shortened, whereby the electric steering lock device 10 can be reduced in size.

  Furthermore, since the lock bolt 44 is actuated via the cam follower 32 made of a spherical ball member, it is possible to prevent the cam groove 50 from being worn or to generate abnormal noise, and the cam follower 32 is provided in the cam groove 50. The resistance when moving with is also reduced.

  Next, in the electric steering lock device 10, when the lock bolt 44 is moved to the lock position, the operation when the engagement recess 4 of the steering shaft 2 does not coincide with the tip of the lock bolt 44 will be described with reference to FIG. 5. I will explain.

  When the locking operation is performed when the tip of the lock bolt 44 does not coincide with the engagement recess 4 of the steering shaft 2, the lock bolt 44 cannot enter the engagement recess 4 of the steering shaft 2, and the tip thereof The vehicle stops halfway in contact with the outer peripheral surface of the steering shaft 2. However, in this case, since the cam follower 32 can move backward along the longitudinal groove 30 of the rotating body 32, the midway stop of the lock bolt 44 does not hinder the rotation of the rotating body 26 and the electric motor 16, and the electric motor 16 As usual, the second detection switch 42 is reversely driven until it is turned off, and then stopped.

  After that, when the steering recess is turned and the engagement recess 4 of the steering shaft 2 coincides with the front end of the lock bolt 44, the front end of the lock bolt 44 is engaged with the engagement recess of the steering shaft 2 by the biasing force of the spring 64. 4 enters and moves to the lock position.

  As described above, in the electric steering lock device 10, even when the lock bolt 44 stops halfway during the locking operation, the electric motor 16 is not overloaded and the electric motor 16 is not operated again. Also, the lock bolt 44 can be moved to the lock position.

  In the present embodiment, the lock bolt 44 is directly engaged with the engagement recess 4 of the steering shaft 2, but is not limited to this. For example, the lock bolt 44 is engaged with the engagement recess 4. Another lock member may be provided, and this lock member may be operated by the lock bolt 44.

Next, an electric steering lock device 70 according to a second embodiment will be described with reference to FIGS.
The electric steering lock device 70 of the present embodiment is different from the electric steering lock device 10 in the following points. In the electric steering lock device 10, a ball member is used as the cam follower 32, but in the electric steering lock device 70 of the present embodiment, a cylindrical roller is used as the cam follower 33. As shown in FIG. 8, the cam follower 33 is integrally provided by insert molding in, for example, a resin rotating body 26, and both ends protrude from the inner peripheral surface of the rotating body 26, for example, a metal shaft 31. Is pivotally supported at the end of the shaft. Therefore, in the electric steering lock device 70, the end portion of the shaft 31 constitutes a holding portion for the cam follower 33. Thus, if the holding | maintenance part of the cam follower 33 is comprised with the metal shafts 31, the holding | maintenance part excellent in durability can be manufactured easily.

  Further, the electric steering lock device 70 has a rectangular cross section of the cam groove 50 formed in the cylindrical portion 46 of the lock bolt 44 in response to the use of a cylindrical roller as the cam follower 33. It is. Further, as shown in FIG. 9, a roller insertion groove 59 that communicates from the extending portion 58 of the cam groove 50 to the end surface of the cylindrical portion 46 is formed. The roller 33 can be inserted into the cam groove 50 through the roller insertion groove 59.

  Further, the width of the inclined portion 52 portion of the cam groove 50 is enlarged in the upward direction (that is, the distal end side of the lock bolt 44), and the upper wall of the enlarged portion 52a is directed from the end portion of the inclined portion 54 toward the circumferential direction. It is formed in a straight line. The enlarged portion 52 a corresponds to the longitudinal groove 30 of the electric steering lock device 10, and is locked when the locking operation is performed when the tip of the lock bolt 44 does not coincide with the engagement recess 4 of the steering shaft 2. Even if the tip of the bolt 44 comes into contact with the outer peripheral surface of the steering shaft 2 and stops, the cam follower 33 can move the enlarged portion 52a of the cam groove 50 in the front-rear direction, so that the lock bolt 44 is stopped halfway. Does not hinder the rotation of the rotating body 26 and the electric motor 16.

  Further, in the electric steering lock device 70, the rotating body 26 is in contact with, for example, three steel balls 72 disposed between the cylindrical support portion 13 protruding from the cover 12. Thereby, the sliding resistance when the rotating body 26 rotates while the urging force of the spring 64 acts via the lock bolt 44 can be reduced.

  Since the other configuration of the electric steering lock device 70 is the same as that of the electric steering lock device 10, the same components are denoted by the same reference numerals and description thereof is omitted.

  The operation of the electric steering lock device 70 configured as described above is almost the same as that of the electric steering lock device 10. In this operation, when the lock bolt 44 moves in the front-rear direction, the roller 33 moves while rotating in the cam groove 50 of the lock bolt 44, so that the ball member 32, which is a cam follower in the electric steering lock device 10, moves to the cam groove 50. The loss of driving force due to friction can be reduced as compared with the case of sliding inside. Thereby, the worm gear diameters of the motor 16 and the rotating body 26 can be reduced, and as a result, the electric steering lock device 70 can be further reduced in size.

The top view of the electric steering lock apparatus of 1st Embodiment of this invention. FIG. 2 is a side sectional view of the electric steering lock device of FIG. 1 in a locked state. The outer peripheral surface expanded view of the cylindrical part of a lock bolt. The side sectional view of the electric steering lock device in the unlocked state. The side sectional view of the electric steering lock device which shows the state where the lock bolt stopped in the middle of moving to the lock position. The top view of the electric steering lock apparatus of 2nd Embodiment of this invention. FIG. 7 is a side sectional view of the electric steering lock device of FIG. 6 in a locked state. Sectional drawing of the rotary body containing the metal shaft which supports a roller. The outer peripheral surface expanded view of the cylindrical part of a lock bolt.

Explanation of symbols

2 ... Steering shaft (movable member)
4 ... engaging recesses 10, 70 ... electric steering lock device 16 ... electric motor 24 ... worm 26 ... rotating body 30 ... vertical groove (holding part)
31 ... Metal shaft (holding part)
32, 33 ... Cam follower 44 ... Lock bolt 46 ... Cylindrical part 50 ... Cam groove 52 ... Slightly inclined part 54 ... Steeply inclined part 64 ... Spring (biasing member)

Claims (5)

In the electric steering lock device configured to lock or unlock the steering by moving the lock bolt with the driving force of the electric motor to engage or disengage the movable member interlocked with the steering operation,
A cam groove that is inclined with respect to the circumferential direction is formed on the outer peripheral surface of the columnar portion of the lock bolt, a cylindrical rotating body that is rotationally driven by the electric motor is provided, and the columnar portion of the lock bolt is It is arranged so as to be movable in the axial direction inside the rotating body, and the lock bolt is moved by moving the cam follower held in the holding portion of the rotating body in the cam groove,
Provided with a biasing member which biases the locking bolt to the movable member side, the holding portion of the rotating body, extending in the direction in which the locking bolt is moved, and the locking bolt during the locking operation of the locking bolt When the front end does not coincide with the engagement recess of the movable member, the cam follower is a vertical groove formed so as to move backward ,
The electric steering lock device according to claim 1, wherein the cam follower moves along the cam groove while being held by the cam groove and the holding portion by rotation of the rotating body.   2. The electric steering lock device according to claim 1, wherein two cam grooves and two cam followers are provided with a shift of approximately 180 degrees.   The inclination angle of the cam groove on the rear end side of the lock bolt is a gentle slope, and the inclination angle of the cam groove on the front end side of the lock bolt is a steep slope. Electric steering lock device.   4. The electric steering lock device according to claim 1, wherein the cam follower is a spherical ball member.   The electric steering lock device according to claim 1, wherein the cam follower is a roller rotatably held by the holding portion of the rotating body.

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