JP2014114004A - Shift lock device - Google Patents

Abstract

PROBLEM TO BE SOLVED: To downsize an actuator of a shift lock device.SOLUTION: A shift lock device 30 provided on an automatic transmission shift lever device 10 equipped with a shift lever 15 and a detent mechanism 22, regulates the releasing action of the detent mechanism 22 in a P range of the shift lever 15, and releases the regulation of the releasing action with the brake operation of a vehicle. The shift lock device 30 includes: a shift lock link 32 moving between a lock position where the releasing action of the detent mechanism 22 is regulated and an unlock position where the regulation is released; a link pring 34 for energizing the shift lock link 32 in an unlocking direction; a solenoid 36 having a plunger working with the brake operation of the vehicle; and a link stopper 38 moving between a regulating position where the movement in the unlocking direction of the shift lock link 32 is regulated and an allowing position where the movement is allowed.

Description

  The present invention relates to a shift lock device provided in a shift lever device for an automatic transmission in a vehicle such as an automobile.

  The shift lock device includes a shift lever that selects one shift range from among a plurality of shift ranges including the P range, and a detent mechanism that holds the shift lever in the P range and releases the hold by operating the detent release button. Is provided in a shift lever device for an automatic transmission including: a detent mechanism that releases the detent mechanism that holds the shift lever in the P range, and the detent mechanism release operation is released in conjunction with the brake operation of the vehicle. (For example, refer to Patent Document 1). In the shift lock device disclosed in Patent Document 1 (referred to as “conventional example”), a lock position for restricting the release operation of the actuating member of the detent mechanism (corresponding to “Lock Pin 24” in Patent Document 1) and an unlocking mechanism for releasing the restriction are disclosed. A shift lock member (same as “stopper”) movably provided at the lock position and an actuator having a plunger (same as “solenoid”) that interlocks with the brake operation of the vehicle. The plunger is connected with a pin.

Japanese Patent Application Laid-Open No. 11-254988

According to the conventional example, since the shift lock member is moved by the thrust (suction force) of the actuator, the actuator required for moving the shift lock member due to the inertia of the shift lock member and the frictional resistance of the sliding portion, etc. There is a limit to reducing the thrust (suction force), and downsizing of the actuator is limited. This hinders weight reduction and cost reduction of the shift lock device.
The problem to be solved by the present invention is to enable downsizing of an actuator of a shift lock device.

Said subject is solved by each following invention.
A first invention is a shift lever that selects one shift range among a plurality of shift ranges including the P range, and a detent mechanism that holds the shift lever in the P range and releases the hold by operating the detent release button. The shift lever device is provided with a shift lever device for an automatic transmission that regulates the release operation of the detent mechanism that holds the shift lever in the P range and releases the restriction of the release operation of the detent mechanism in conjunction with the brake operation of the vehicle A lock device, a shift lock member provided so as to be movable between a lock position for restricting the release operation of the actuating member of the detent mechanism and an unlock position for releasing the restriction, and the shift lock member attached in the unlock direction. Actuator having an elastic member that urges and a plunger that interlocks with the brake operation of the vehicle , And a stopper member which is moved by an actuator plunger at the restricting position to restrict the movement of the unlocking direction of the shift lock member and a permitting position for permitting the movement.

  According to this configuration, when the shift lock member is in the locked position with the shift lever held by the detent mechanism in the P range, the release operation of the operating member of the detent mechanism is restricted by the shift lock member. Further, when the stopper member is in the restriction position, the movement of the shift lock member to the unlock position due to the biasing of the elastic member is restricted. For this reason, the shift lever cannot be shifted from the P range to another shift range. In this state, when the actuator is operated in conjunction with the brake operation of the vehicle, the stopper member is moved to the allowable position together with the plunger of the actuator. Further, the shift lock member is moved to the unlock position by the biasing of the elastic member. Therefore, the shift lever can be shifted from the P range to another shift range by releasing the holding of the shift lever by the detent mechanism by operating the detent release button.

  By the way, by moving the stopper member to the restriction position by the actuator, the movement of the shift lock member to the unlock position by the biasing of the elastic member is restricted, and by moving the stopper member to the allowable position by the actuator, The shift lock member is allowed to move to the unlock position by the biasing of the elastic member. Therefore, the actuator has a thrust force necessary to move the stopper member to a restriction position that restricts the movement of the shift lock member to the unlock position by the urging of the elastic member and an allowable position that permits the movement. What is necessary is just to have a small thrust compared with the thrust required for moving a shift lock member like a prior art example. For this reason, it is possible to reduce the size of the actuator of the shift lock device.

  In addition, since the operation stroke of the plunger of the actuator can be shortened, the actuator of the shift lock device can be downsized. Further, although the stopper member is integrally moved by the plunger of the actuator, there is no member (for example, a conventional shift lock member) connected to the plunger by a pin or the like, so that the operation noise can be reduced. .

  According to a second invention, in the first invention, lock-side engagement means is provided between the shift lock member and the stopper member, and the lock-side engagement means includes a locking portion provided on one member; The engaging member is provided on the other member and is detachably provided on the locking part. The engagement of the locking part and the engaging part restricts the movement of the shift lock member in the unlocking direction. The configuration is as follows. According to this configuration, the movement of the shift lock member in the unlocking direction is restricted by the engagement between the engaging portion and the engaging portion of the lock-side engaging means provided between the shift lock member and the stopper member. be able to.

  According to a third invention, in the first or second invention, in the P range of the shift lever, the shift lock member is held at the lock position by the operating member of the detent mechanism. According to this configuration, in the P range of the shift lever, the shift lock member can be held at the lock position using the operating member of the detent mechanism.

  According to a fourth invention, in the third invention, in the P range of the shift lever, the shift lock member is moved from the unlock position to the lock position by using the return operation of the operating member of the detent mechanism. According to this configuration, in the P range of the shift lever, the shift lock member can be moved from the unlock position to the lock position using the return operation of the operating member of the detent mechanism.

  According to a fifth invention, in the first to fourth inventions, the shift lock member moved in the unlocking direction by the elastic member is stopped at the unlock position by the stopper member. According to this configuration, the shift lock member that is moved in the unlocking direction by the elastic member can be stopped at the unlock position by the stopper member.

1 is a front view showing a shift lever device for an automatic transmission according to a first embodiment. It is a left view which shows a shift lever apparatus. It is a right view which shows a shift lever apparatus. It is a left view which shows the peripheral part of a shift lock apparatus. It is a perspective view which decomposes | disassembles and shows a shift lock apparatus. It is a left view which shows a shift lock apparatus roughly. It is a rear view which shows a shift lock apparatus roughly. It is a disassembled perspective view which shows a lock side engaging means and an unlocking side engaging means. It is operation | movement explanatory drawing of a shift lock apparatus. It is operation | movement explanatory drawing of a shift lock apparatus. It is operation | movement explanatory drawing of a shift lock apparatus. It is operation | movement explanatory drawing of a shift lock apparatus. It is operation | movement explanatory drawing of a shift lock apparatus. It is a disassembled perspective view which shows the lock side engaging means and unlocking side engaging means concerning Embodiment 2. FIG. It is a disassembled perspective view which shows the lock side engaging means and unlocking side engaging means concerning Embodiment 3. FIG. It is a left view which shows the lock side engaging means and unlock side engaging means concerning Embodiment 4. It is operation | movement explanatory drawing of a shift lock apparatus. It is operation | movement explanatory drawing of a shift lock apparatus. It is operation | movement explanatory drawing of a shift lock apparatus. It is operation | movement explanatory drawing of a shift lock apparatus. It is a left view which shows the lock side engagement means and unlock side engagement means concerning Embodiment 5. It is action explanatory drawing of a lock side engaging means.

  Hereinafter, embodiments for carrying out the present invention will be described with reference to the drawings.

[Embodiment 1]
Embodiment 1 will be described. First, the basic configuration of a shift lever device for an automatic transmission (hereinafter referred to as “shift lever device”) will be described. 1 is a front view showing the shift lever device, FIG. 2 is a left side view, and FIG. 3 is a right side view. In the figure, arrow UP indicates the upper side of the vehicle, RH indicates the right side of the vehicle, and FR indicates the front side of the vehicle. The basic configuration of the shift lever device is the same as the basic configuration except the shift lock device of the shift lever device described in Japanese Patent Application Laid-Open No. 2013-1346.

  As shown in FIGS. 1-3, the shift lever apparatus 10 is provided with the base bracket 12 fixed to a vehicle body side member (illustration omitted). A shift panel 13 is disposed on the upper surface side of the base bracket 12. A shift lever 15 is supported by the base bracket 12 via a shift shaft 16 (see FIG. 2) so as to be rotatable with the front-rear direction as a shift direction. One end side (upper end side) of the shift lever 15 protrudes upward, that is, toward the passenger compartment through the shift panel 13 (specifically, a long hole-like opening extending in the front-rear direction).

  The lever body 17 of the shift lever 15 is formed in a hollow shaft shape. A shift knob 18 is attached to the upper end of the lever body 17. A control lever 20 that protrudes forward is provided at the lower end of the lever body 17 (see FIG. 3). A shift cable linked to an automatic transmission (not shown) is connected to the control lever 20. The shift operation of the shift lever 15 is transmitted to the automatic transmission via the shift cable. In addition, the parking range (P range), reverse range (R range), neutral range (N range), drive range (D range), second range (2 range), low range (L range) as the shift range of the shift lever 15 Are arranged in order so as to form a straight shape from the front side to the rear side. The shift lever 15 selects one of these shift ranges.

  The shift lever device 10 includes a detent mechanism 22 that holds the shift lever 15 in the P range and releases the hold by operating a shift button 26 (see FIG. 1). The detent mechanism 22 includes a detent rod 23, a shift button 26, a detent portion 28 (see FIG. 2), and the like. The detent rod 23 is disposed in the hollow portion of the lever body 17 so as to be movable in the axial direction. At the lower end of the detent rod 23, a lock pin 24 (see FIG. 2) made of a grooved pin is provided. The detent rod 23 is elastically biased downward by a spring (not shown). The detent rod 23 having the lock pin 24 corresponds to an “operating member” in the present specification.

The shift button 26 (see FIG. 1) is disposed so that it can be pushed into the shift knob 18. The detent mechanism 22 is configured so that the detent rod 23 can be pulled up against the urging of a spring (not shown) by pressing the shift button 26. When the pushing operation of the shift button 26 is released, the shift button 26 is pushed back by the biasing of a spring (not shown), and the detent rod 23 is pushed down by the biasing of the spring (not shown), that is, returned. The shift button 26 corresponds to a “detent release button” in this specification.
Further, the detent portion 28 (partially shown in FIG. 2) is formed in the base bracket 12, and is formed by an opening hole that movably accommodates the lock pin 24 of the detent rod 23. Yes. A step-like detent groove (not shown) with which the lock pin 24 engages or abuts is formed at the lower edge of the detent portion 28.

  In the P range of the shift lever 15, the detent mechanism 22 is configured so that the shift lever 15 is held or locked in the P range by engaging the lock pin 24 of the detent rod 23 with the detent groove corresponding to the P range. It has become. When the shift button 26 is pushed in and the detent rod 23 is pulled up, the engagement of the lock pin 24 with the detent groove corresponding to the P range is released, that is, unlocked. Thereby, the shift lever 15 can be shifted to a shift range other than the P range. When shifting from a shift range other than the P range to the P range, if the shift button 15 is shifted to the P range while the shift button 26 is pressed, the detent is released when the shift button 26 is released. The rod 23 is pushed down by the spring, and the lock pin 24 engages with the detent groove corresponding to the P range. As a result, the shift lever 15 is held or locked in the P range.

  The shift lever device 10 having the basic configuration described above restricts the release operation of the detent mechanism 22 that holds the shift lever 15 in the P range, and restricts the release operation of the detent mechanism 22 in conjunction with the brake operation of the vehicle. A shift lock device 30 for releasing is provided (see FIG. 2).

Next, the shift lock device 30 will be described. 4 is a left side view showing the periphery of the shift lock device, FIG. 5 is an exploded perspective view showing the shift lock device, FIG. 6 is a left side view schematically showing the shift lock device, and FIG. It is.
As shown in FIG. 5, the shift lock device 30 includes a shift lock link 32, a link spring 34, a solenoid 36, a link stopper 38, and the like.

  The shift lock link 32 is rotatably supported by the base bracket 12 via a support shaft 40 (see FIG. 4). The support shaft 40 is arranged near the shift shaft 16 so as to be parallel to the shift shaft 16. The shift lock link 32 includes a lever portion 42 that extends downward from the support shaft 40 side, and an arm portion 44 that is formed at the rear edge of the lever portion 42. As shown in FIGS. 6 and 7, the lower end portion of the lever portion 42 is a restricting portion 43 that faces the upper side of the lock pin 24 of the detent rod 23 at the holding position of the shift lever 15 in the P range.

  The arm portion 44 extends along the rear side edge of the lever portion 42 (see FIG. 6). Moreover, the arm part 44 is formed in the wide shape which protrudes from the arm part 44 to the left side (refer FIG. 7). Further, the lower end portion of the arm portion 44 extends downward from the restricting portion 43. A cam portion 45 is formed at the lower end portion of the arm portion 44 and extends so as to be gently folded back forward (leftward in FIG. 6). The shift lock link 32 corresponds to a “shift lock member” in this specification.

  The link spring 34 is a torsion coil spring, and is interposed between the base bracket 12 and the shift lock link 32 (see FIG. 6). The coil portion of the link spring 34 is fitted on the support shaft 40. One end portion of the link spring 34 is hooked to the base bracket 12, and the other end portion is hooked to the shift lock link 32. Further, the link spring 34 elastically biases the shift lock link 32 in the unlocking direction (see arrow Y in FIG. 6). The link spring 34 corresponds to an “elastic member” in the present specification.

  The solenoid 36 is disposed on the base bracket 12 (see FIG. 4). The solenoid 36 is arranged on the rear side (right side in FIG. 4) of the support shaft 40 with the plunger 37 facing the front, that is, the upper end of the shift lock link 32. The solenoid 36 is a pull-type electromagnetic solenoid into which a plunger 37 is drawn in response to energization of a built-in solenoid coil. The solenoid 36 is actuated, that is, energized by a control device (ECU) (not shown) based on the brake operation of the vehicle, that is, the depression operation of the brake pedal in a state where the shift lever 15 is in the P range. The plunger 37 is retracted (retracted). In addition, when the energization is turned off by the control unit (ECU) based on the release of the brake operation of the vehicle, the plunger 37 is pushed out (expanded) by urging of a solenoid spring 47 (described later). Yes. The solenoid 36 corresponds to an “actuator” in this specification.

  The link stopper 38 is attached to the tip of the plunger 37 of the solenoid 36 (see FIG. 4). The link stopper 38 is formed in a rectangular block shape and is urged in the advance direction (forward) by a solenoid spring 47 formed of a coil spring (see FIG. 6). The solenoid spring 47 is fitted to the plunger 37 and is interposed between a solenoid (specifically, a solenoid body) 36 and a link stopper 38. Further, the advance position of the link stopper 38 when the solenoid 36 is in an off state (non-energized state) corresponds to a restriction position that restricts the movement of the shift lock link 32 in the unlocking direction (see the solid line 38 in FIG. 6). Further, the retracted position of the link stopper 38 when the solenoid 36 is in the ON state (energized state) corresponds to an allowable position that allows the shift lock link 32 to move in the unlocking direction (see a two-dot chain line 38 in FIG. 6). The link stopper 38 corresponds to a “stopper member” in this specification.

Between the opposed portions of the shift lock link 32 and the link stopper 38, there are provided lock side engagement means and unlock side engagement means that can be engaged and disengaged with each other. FIG. 8 is an exploded perspective view showing the lock side engagement means and the unlock side engagement means.
As shown in FIG. 8, the lock-side engaging means includes an engaging portion 50 provided on the shift lock link 32, and an engaging portion provided on the link stopper 38 and detachably provided on the engaging portion 50. 52. The locking portion 50 protrudes in a triangular prism shape extending in the left-right direction at the upper end portion of the rear side surface of the arm portion 44 of the shift lock link 32. The upper surface of the locking portion 50 is a locking surface 51 that is a flat surface. Further, the engaging portion 52 is formed by an upper half portion that projects in a stepped manner from the lower half portion of the front end surface (front surface) of the link stopper 38. The lower surface of the engaging portion 52 is an engaging surface 53 that is a flat surface corresponding to the locking surface 51 of the locking portion 50. The engagement (contact) of the engaging portion 50 (specifically, the engaging surface 51) and the engaging portion 52 (specifically, the engaging surface 53) restricts the rotation of the shift lock link 32 in the unlocking direction. The Further, the link stopper 38 is held in the restricting position by contact between the locking portion 50 (specifically, the rear end portion of the locking surface 51) and the front surface of the receiving portion 55 (described later) (see FIG. 6). .

  As shown in FIG. 8, a receiving portion 55 is formed by a corner portion formed by the lower half portion and the lower surface of the distal end surface of the link stopper 38. The lower surface of the receiving portion 55 (the lower surface of the link stopper 38) is a flat receiving surface 56. Further, a stepped contact portion 57 is formed on the rear side surface of the arm portion 44 of the shift lock link 32 so as to continue below the locking portion 50. A stepped surface (upper surface) of the contact portion 57 is a contact surface 58 that is a flat surface corresponding to the receiving surface 56 of the receiving portion 55. The shift lock link 32 and the link stopper 38 are stopped at the unlock position by the engagement (contact) of the receiving portion 55 (specifically, the receiving surface 56) and the contact portion 57 (specifically, the contact surface 58). (See FIG. 12 or FIG. 13). In addition, the receiving part 55 and the contact part 57 comprise the unlocking side engaging means. Further, the locking surface 51 and the contact surface 58 are connected in a stepped manner through a flat wall surface 59 (see FIG. 8).

  As shown in FIG. 5, a lock release pin 60 projects from one side surface (left side surface) of the link stopper 38. The shift panel 13 is provided with a shift lock release button 62 so that it can be pushed in. The shift lock release button 62 has a lock release arm 63 extending downward in an inverted L shape. A forwardly inclined slope 64 is formed at the lower end of the unlocking arm 63. The slope 64 of the unlocking arm 63 is close to the front side of the unlocking pin 60 of the link stopper 38 at the restricting position (see FIG. 4). When the shift lock release button 62 is pushed in, the inclined surface 64 of the lock release arm 63 comes into sliding contact with the lock release pin 60 of the link stopper 38, and the plunger 37 of the solenoid 36 together with the link stopper 38 biases the solenoid spring 47. It is pushed against. Thereby, engagement of the engaging part 52 of the link stopper 38 with respect to the engaging part 50 of the shift lock link 32 in the locked position can be released. That is, the shift lock of the shift lock device 30 can be released manually. When the pushing operation of the shift lock release button 62 is released, the shift lock release button 62 is pushed back by the bias of a spring (not shown).

Next, the operation of the shift lever device 10 including the shift lock device 30 will be described.
Now, it is assumed that the shift lever 15 is in the P range and the shift lever 15 is held in the P range by the detent mechanism 22 (see FIGS. 2 and 4). Further, the solenoid 36 is in an OFF state, and the link stopper 38 is positioned at the restriction position. In this state (referred to as “shift lock state”), as shown in FIGS. 6 and 7, the lock pin 24 of the detent rod 23 is formed between the arm portion 44 and the cam portion 45 of the shift lock link 32. It is located in the U-shaped concave portion 46. That is, the shift lock link 32 is held in the locked position by the lock pin 24 of the detent rod 23 of the detent mechanism 22. At this time, the engaging portion 50 of the shift lock link 32 faces the engaging portion 52 of the link stopper 38 via the gap C1 (see FIG. 6). Further, the front surface of the receiving portion 55 of the link stopper 38 biased by the solenoid spring 47 is elastically brought into contact with the rear end portion of the locking portion 50, so that the link stopper 38 is held at the restriction position.

In the shift lock state (see FIGS. 6 and 7), when the driver pushes the shift button 26 (see FIG. 1) without operating the brake when driving the vehicle, the detent rod 23 is lifted and locked. The pin 24 moves away from the concave portion 46 of the shift lock link 32. As a result, the shift lock link 32 tends to rotate in the unlocking direction (see arrow Y in FIG. 6) by the urging force of the link spring 34. However, the locking portion 50 (specifically, the locking surface 51 (see FIG. 8)) of the shift lock link 32 is immediately engaged with the engaging portion 52 (specifically, the engaging surface 53 (see FIG. 8)) of the link stopper 38. (Contact) restricts the rotation of the shift lock link 32 in the unlocking direction (see FIG. 9).
For this reason, when the lock pin 24 of the detent rod 23 in the middle of being pulled up by the pushing operation of the shift button 26 abuts on the regulating portion 43 of the shift lock link 32, further lifting operation of the detent rod 23 is regulated ( (See FIG. 10). That is, the release operation of the detent mechanism 22 is restricted. For this reason, the shift lever 15 cannot be shifted from the P range to another shift range. It should be noted that the engaging portion 52 (specifically, the engaging surface 53 (see FIG. 8)) of the link stopper 38 and the engaging portion 50 (specifically, the engaging surface 51 (see FIG. 8) of the shift lock link 32 at the restricting position (advance position). 8))), a predetermined engagement allowance A (see FIG. 9) is set. Note that by setting the engagement allowance A small, the operation stroke of the solenoid 36 can be shortened, and the solenoid 36 can be downsized.

  In the shift lock state (see FIG. 6), when the solenoid 36 is turned on in conjunction with the braking operation of the vehicle, the link stopper 38 is pulled together with the plunger 37 (see the two-dot chain line 38 in FIG. 6). Thereby, since the link stopper 38 is retracted to the allowable position, the engagement of the engaging portion 52 of the link stopper 38 with the engaging portion 50 of the shift lock link 32 is released. Subsequently, when the driver pushes the shift button 26 (see FIG. 1), the lock pin 24 moves away from the concave portion 46 of the shift lock link 32 as the detent rod 23 is pulled up. Accordingly, the shift lock link 32 is rotated in the unlocking direction (see arrow Y in FIG. 6) by the urging force of the link spring 34 (see FIG. 11). At this time, the cam portion 45 of the shift lock link 32 slides along the lock pin 24. Further, since the link stopper 38 is in the allowable position (retracted position), the engaging portion 50 of the shift lock link 32 is not engaged with the engaging portion 52 of the link stopper 38. Specifically, since the gap C2 (see FIG. 11) is set between the engaging portion 52 of the link stopper 38 and the engaging portion 50 of the shift lock link 32, the engaging portion 50 is engaged with the engaging portion 52. Do not match.

  Then, when the contact portion 57 of the shift lock link 32 of the shift lock link 32 rotated in the unlocking direction (see arrow Y in FIG. 6) is engaged with the receiving portion 55 of the link stopper 38, The shift lock link 32 is stopped at the unlock position (see FIG. 12). In this state (unlocked state), the lock pin 24 of the detent rod 23 that is being pulled up by the pushing operation of the shift button 26 (see FIG. 1) is pulled up without coming into contact with the restricting portion 43 of the shift lock link 32. That is, the holding of the shift lever 15 by the detent mechanism 22 is released. Accordingly, the shift lever 15 can be shifted from the P range to another shift range. It should be noted that the receiving portion 55 (detailed receiving surface 56 (see FIG. 8)) of the link stopper 38 and the contact portion 57 (detailed contact surface 58 (detailed) of the shift lock link 32) in the link stopper 38 in the allowable position (retracted position). 8))), a predetermined engagement allowance B (see FIG. 12) is set.

  Further, the solenoid 36 may be turned off after the shift lock link 32 is stopped at the unlock position. That is, when the solenoid 36 is in an off state (non-energized state), the urging force of the solenoid spring 47 is only acting on the plunger 37. Therefore, even if the link stopper 38 is advanced by the solenoid spring 47, the engaging portion 52 (specifically, the front end surface (front surface)) of the link stopper 38 elastically contacts the wall surface 59 of the shift lock link 32 opposed thereto. Therefore, the link stopper 38 cannot advance any further.

  In the unlocked state (see FIG. 12), when the shift lever 15 is in a shift range other than the P range, the shift button 26 (see FIG. 1) is pushed and the detent rod 23 is lifted to shift to the P range. After the operation (see the two-dot chain line 24 (23) in FIG. 13), the pushing operation of the shift button 26 is released. Then, as the detent rod 23 is pushed down to the holding position of the shift lever 15 by a spring (not shown), the lock pin 24 is engaged with a detent groove (not shown) corresponding to the P range. As the detent rod 23 is pushed down (return operation), the lock pin 24 comes into contact with the tip of the cam portion 45 of the shift lock link 32 (see the solid line 24 (23) in FIG. 13). Thereafter, when the lock pin 24 is moved downward, the cam portion 45 is slid forward along the lock pin 24, so that the shift lock link 32 is rotated to the lock position against the bias of the link spring 34. The Finally, the lock pin 24 is positioned in the concave portion 46 of the shift lock link 32, so that the shift lock link 32 is held in the lock position, resulting in the shift lock state (see FIG. 6). Accordingly, the link stopper 38 is returned to the restricting position (advance position) by the urging of the solenoid spring 47.

  Further, when the solenoid 36 is in an off state (non-energized state), the urging force of the solenoid spring 47 is only acting on the plunger 37 having the link stopper 38. Therefore, when the shift lock link 32 is rotated from the unlock position to the lock position, the rear end portion of the locking portion 50 of the shift lock link 32 (specifically, the corner portion formed by the locking surface 51 and the first wall surface 59). ) Interferes with the receiving portion 55 (specifically, the front surface) of the link stopper 38, the link stopper 38 is pushed in the reverse direction against the bias of the solenoid spring 47. Then, when the locking portion 50 finishes passing through the engaging portion 52, the link stopper 38 is returned to the advanced position (regulated position) by the urging of the solenoid spring 47 (see FIG. 6).

  According to the shift lock device 30, when the shift lever 15 is held by the detent mechanism 22 in the P range and the shift lock link 32 is in the locked position, the detent rod 23 of the detent mechanism 22 is moved by the shift lock link 32. The release operation of the lock pin 24 is restricted. Further, when the link stopper 38 is in the restriction position, the shift lock link 32 is prevented from moving to the unlock position by the urging of the link spring 34. For this reason, the shift lever 15 cannot be shifted from the P range to another shift range. In this state, when the solenoid 36 is operated in conjunction with the brake operation of the vehicle, the link stopper 38 is moved to the allowable position together with the plunger 37 of the solenoid 36. Further, the shift lock link 32 is moved to the unlock position by the bias of the link spring 34. Therefore, the shift lever 15 can be shifted from the P range to another shift range by releasing the hold of the shift lever 15 by the detent mechanism 22 by operating the shift button 26.

  By the way, the movement of the shift lock link 32 to the unlock position by the bias of the link spring 34 is regulated by moving the link stopper 38 to the regulation position by the solenoid 36, and the link stopper 38 is moved to the allowable position by the solenoid 36. The shift lock link 32 is allowed to move to the unlock position due to the urging of the link spring 34. Therefore, the solenoid 36 has a thrust force required to move the link stopper 38 to a restriction position that restricts the movement of the shift lock link 32 to the unlock position by the bias of the link spring 34 and an allowable position that allows the movement. As long as the thrust required to move the shift lock link as in the conventional example is small. For this reason, the solenoid 36 of the shift lock device 30 can be downsized. As a result, the shift lock device 30 can be reduced in size and cost.

  Further, the operating stroke of the plunger 37 of the solenoid 36 can also be shortened, so that the solenoid 36 of the shift lock device 30 can be downsized. Further, although the link stopper 38 is integrally moved by the plunger 37 of the solenoid 36, there is no member (for example, the shift lock link 32 of the conventional example) connected to the plunger 37 with a pin or the like, so that the operation sound is not generated. Can be reduced.

  In addition, the unlocking direction of the shift lock link 32 (in FIG. 6) is achieved by the engagement of the engaging portion 50 and the engaging portion 52 of the lock side engaging means provided between the shift lock link 32 and the link stopper 38. , (See arrow Y) can be restricted.

  Further, in the P range of the shift lever 15, the shift lock link 32 can be held at the lock position by using the lock pin 24 of the detent rod 23 of the detent mechanism 22.

  In the P range of the shift lever 15, the shift lock link 32 can be moved from the unlock position to the lock position by using the return operation of the lock pin 24 of the detent rod 23 of the detent mechanism 22.

  Further, the shift stopper link 32 that is moved in the unlocking direction (see arrow Y in FIG. 6) by the link spring 34 can be stopped at the unlock position by the link stopper 38.

[Embodiment 2]
A second embodiment will be described. Since the present embodiment is a modification of the first embodiment, the changed portion will be described and redundant description will be omitted. FIG. 14 is an exploded perspective view showing the lock side engagement means and the unlock side engagement means.
As shown in FIG. 14, in the present embodiment, the engagement surface 53 (see FIG. 8) of the engagement portion 52 of the link stopper 38 in the first embodiment is changed to an engagement surface 53A composed of a convex arc surface. It is a thing. Thereby, even if the link stopper 38 rattles around the axis of the plunger 37, the engagement surface 51 of the engagement portion 50 of the shift lock link 32 with respect to the engagement surface 53A of the engagement portion 52 of the link stopper 38 is engaged. Can be ensured.

[Embodiment 3]
A third embodiment will be described. Since the present embodiment is a modification of the first embodiment, the changed portion will be described and redundant description will be omitted. FIG. 15 is an exploded perspective view showing the lock-side engagement means and the unlock-side engagement means.
As shown in FIG. 15, in the present embodiment, a hemispherical protrusion 54 is formed at the center of the engagement surface 53 (see FIG. 8) of the engagement portion 52 of the link stopper 38 in the first embodiment. It is. Thereby, even if the link stopper 38 rattles around the axis of the plunger 37, the engagement surface 51 of the engagement portion 50 of the shift lock link 32 engages with the projection 54 of the engagement portion 52 of the link stopper 38. Can be ensured.

[Embodiment 4]
A fourth embodiment will be described. Since the present embodiment is a modification of the first embodiment, the changed portion will be described and redundant description will be omitted. FIG. 16 is a left side view showing the lock side engagement means and the unlock side engagement means.
As shown in FIG. 16, in this embodiment, the engaging portion 52 (including the locking surface 53) of the link stopper 38 (see FIG. 8) in the first embodiment is omitted. For this reason, an engaging portion and receiving portion 70 that serves as both an engaging portion and a receiving portion is formed by a corner portion formed by the flat front surface 71 and the flat lower surface 72 of the link stopper 38. . Further, the lower surface 72 of the engagement portion / reception portion 70 is an engagement surface / reception surface 72 (denoted by the same reference numeral as the lower surface) that doubles as a locking surface and a reception surface.

  Therefore, the engaging portion 50 (specifically, the engaging surface 51) of the shift lock link 32 and the engaging portion / receiving portion 70 (specifically the engaging surface / receiving surface 72) of the link stopper 38 are engaged. The shift lock link 32 is held in the locked position (see FIG. 17). In addition, the engagement between the contact portion 57 (specifically, the contact surface 58) of the shift lock link 32 and the engagement portion / reception portion 70 (specifically, the engagement surface / reception surface 72) of the link stopper 38. ), The shift lock link 32 and the link stopper 38 are stopped at the unlock position (see FIG. 19). In addition, the engaging portion / receiving portion 70 and the locking portion 50 constitute a lock side engaging means, and the engaging portion / receiving portion 70 and the contact portion 57 constitute an unlocking side engaging means. ing.

  On the other hand, the locking portion 50 of the shift lock link 32 is formed with a wall surface 74 formed of a plane rising from the front portion of the upper surface of the locking surface 51. The front surface 71 of the engaging / receiving portion 70 of the link stopper 38 urged by the solenoid spring 47 can be elastically contacted with the wall surface 74. Hereinafter, the wall surface 59 is referred to as a “first wall surface 59”, and the wall surface 74 is referred to as a “second wall surface 74”.

Next, the operation of the shift lock device 30 will be described.
In the shift lock state, as shown in FIG. 17, the lock pin 24 of the detent rod 23 is positioned in the concave portion 46 of the shift lock link 32. That is, the shift lock link 32 is held in the locked position by the lock pin 24 of the detent rod 23 of the detent mechanism 22. Further, the solenoid 36 is in an OFF state, and the link stopper 38 is positioned at the restriction position. Further, the engaging portion 50 (specifically, the engaging surface 51) of the shift lock link 32 and the engaging portion / receiving portion 70 (specifically, the engaging surface / receiving surface 72) of the link stopper 38 are engaged. The shift lock link 32 is held in the locked position. Further, the front surface 71 of the engaging portion / receiving portion 70 of the link stopper 38 biased by the solenoid spring 47 elastically abuts against the second wall surface 74 of the locking portion 50, so that the link stopper 38 is in the restricted position. Retained. It should be noted that the engaging portion / receiving portion 70 (specifically, engaging surface / receiving surface 72) of the link stopper 38 and the engaging portion 50 (specifically, engaging surface) of the shift lock link 32 at the restricting position (advance position). 51), a predetermined engagement allowance A1 (see FIG. 17) is set.

  In the shift lock state (see FIG. 17), when the driver pushes down the shift button 26 (see FIG. 1) without operating the brake when driving the vehicle, the lock pin 24 is moved as the detent rod 23 is pulled up. It moves away from the concave portion 46 of the shift lock link 32. As a result, the shift lock link 32 tends to rotate in the unlocking direction (see arrow Y in FIG. 17) by the urging force of the link spring 34. However, the engaging portion 50 (specifically, the engaging surface 51) of the shift lock link 32 is engaged (contacted) with the engaging portion / receiving portion 70 (specifically, engaging surface / receiving surface 72) of the link stopper 38. Therefore, the rotation of the shift lock link 32 in the unlocking direction is restricted.

  For this reason, when the lock pin 24 of the detent rod 23 in the middle of being pulled up by the pushing operation of the shift button 26 abuts on the regulating portion 43 of the shift lock link 32, further lifting operation of the detent rod 23 is regulated ( (See FIG. 18). That is, since the releasing operation of the detent mechanism 22 is restricted, the shift lever 15 cannot be shifted from the P range to another shift range.

  In the shift lock state (see FIG. 17), when the solenoid 36 is turned on in conjunction with the brake operation of the vehicle, the link stopper 38 is pulled together with the plunger 37 (see the two-dot chain line 38 in FIG. 17). As a result, the link stopper 38 is retracted to the permissible position, and the engagement of the engaging portion / receiving portion 70 of the link stopper 38 with the engaging portion 50 of the shift lock link 32 is released. Subsequently, when the driver pushes the shift button 26 (see FIG. 1), the lock pin 24 moves away from the concave portion 46 of the shift lock link 32 as the detent rod 23 is pulled up. Accordingly, the shift lock link 32 is rotated in the unlocking direction (see arrow Y in FIG. 17) by the urging force of the link spring 34.

  Then, the abutment portion 57 of the shift lock link 32 of the shift lock link 32 rotated in the unlocking direction is engaged with the engaging portion / receiving portion 70 of the link stopper 38, whereby the shift lock link 32 is It stops at the unlock position (see FIG. 19). In this state (unlocked state), the lock pin 24 of the detent rod 23 that is being pulled up by the pushing operation of the shift button 26 (see FIG. 1) is pulled up without coming into contact with the restricting portion 43 of the shift lock link 32. That is, the holding of the shift lever 15 by the detent mechanism 22 is released. Accordingly, the shift lever 15 can be shifted from the P range to another shift range. The engaging / receiving portion 70 (specifically, engaging surface / receiving surface 72) of the link stopper 38 and the abutting portion 57 (specifically, the contacting surface) of the shift lock link 32 at the allowable position (retracted position). 58), a predetermined engagement allowance B1 (see FIG. 19) is set.

  Further, the solenoid 36 may be turned off after the shift lock link 32 is stopped at the unlock position. That is, when the solenoid 36 is in an off state (non-energized state), the urging force of the solenoid spring 47 is only acting on the plunger 37. Therefore, even if the link stopper 38 is advanced by the solenoid spring 47, the engaging portion / receiving portion 70 (specifically, the front surface 71) of the link stopper 38 is elastically applied to the first wall surface 59 of the shift lock link 32 facing it. The link stopper 38 cannot advance any further.

  In the unlocked state (see FIG. 19), when the shift lever 15 is in a shift range other than the P range, the shift button 26 (see FIG. 1) is pushed into the P range while the detent rod 23 is pulled up. After the operation (see the two-dot chain line 24 (23) in FIG. 20), the pushing operation of the shift button 26 is released. Then, as the detent rod 23 is pushed down to the holding position of the shift lever 15 by a spring (not shown), the lock pin 24 is engaged with a detent groove (not shown) corresponding to the P range. As the detent rod 23 is pushed down (return operation), the lock pin 24 comes into contact with the tip of the cam portion 45 of the shift lock link 32 (see the solid line 24 (23) in FIG. 20). Thereafter, when the lock pin 24 is moved downward, the cam portion 45 is slid forward along the lock pin 24, so that the shift lock link 32 is rotated to the lock position against the bias of the link spring 34. The Finally, the lock pin 24 is positioned in the concave portion 46 of the shift lock link 32, so that the shift lock link 32 is held in the lock position, resulting in the shift lock state (see FIG. 17). Accordingly, the link stopper 38 is returned to the restricting position (advance position) by the urging of the solenoid spring 47.

  Further, when the solenoid 36 is in an off state (non-energized state), the urging force of the solenoid spring 47 is only acting on the plunger 37 having the link stopper 38. Therefore, when the shift lock link 32 is rotated from the unlock position to the lock position, the rear end portion of the locking portion 50 of the shift lock link 32 (specifically, the corner portion formed by the locking surface 51 and the first wall surface 59). ) Interferes with the front surface 71 of the engaging portion / receiving portion 70 of the link stopper 38, the link stopper 38 is pushed in the backward direction against the bias of the solenoid spring 47. When the locking portion 50 has finished passing through the engaging portion and receiving portion 70, the link stopper 38 is returned to the advanced position (regulated position) by the bias of the solenoid spring 47 (see FIG. 17).

[Embodiment 5]
A fifth embodiment will be described. Since this embodiment adds the change to the said Embodiment 4, the changed part is demonstrated and the overlapping description is abbreviate | omitted. FIG. 21 is a left side view showing the lock-side engagement means and the unlock-side engagement means, and FIG. 22 is an operation explanatory view of the lock-side engagement means.
As shown in FIG. 21, in the present embodiment, the second wall surface 74 of the shift lock link 32 in the fourth embodiment is set to a height 74 h that is lower than the height 59 h of the first wall surface 59. The shift lock link 32 is formed of a material that is less likely to be worn than the material of the link stopper 38. When the shift lock link 32 and the link stopper 38 are made of resin, for example, a glass-filled nylon resin is used for the shift lock link 32 and a polyacetal resin is used for the link stopper 38. The shift lock link 32 and the link stopper 38 are not limited to resin, and at least the shift lock link 32 may be made of metal.

  When the shift lock link 32 is rotated from the unlock position to the lock position, the rear end portion of the engaging portion 50 of the shift lock link 32 interferes with the front portion 71 of the engaging portion / receiving portion 70 of the link stopper 38. Thus, wear occurs on the lower portion of the front surface 71 of the engaging / receiving portion 70 of the link stopper 38 (see the two-dot chain line 71a in FIG. 22). In FIG. 22, an alternate long and two short dashes line 71 a that indicates the worn state of the front surface 71 of the engaging and receiving portion 70 is exaggerated.

  However, when the link stopper 38 is biased by the solenoid spring 47 in the shift lock state, the link stopper 38 is moved forward (leftward in FIG. 22) from the initial position (see the solid line 38 in FIG. 22). The That is, the front surface 71 (specifically, the front end surface 71a retracted due to wear) of the engaging portion / receiving portion 70 is elastically brought into contact with the second wall surface 74 of the locking portion 50 (in FIG. 22, a two-dot chain line). 38). As a result, the link stopper 38 is held at the restriction position. For this reason, the engaging portion / receiving portion 70 (specifically, engaging surface / receiving surface 72) of the link stopper 38 and the engaging portion 50 (specifically, engaging portion) of the shift lock link 32 at the restriction position (advance position). The engagement allowance A1 with the surface 51) is secured. Therefore, even if wear occurs on the front surface 71 of the engagement portion / reception portion 70 of the link stopper 38, the engagement portion / reception portion 70 (specifically, engagement surface / reception portion of the link stopper 38) over a long period of time. The engagement relationship between the surface 72) and the locking portion 50 (specifically, the locking surface 51) of the shift lock link 32 can be continued.

  The present invention is not limited to the above-described embodiment, and modifications can be made without departing from the gist of the present invention. For example, the actuator is not limited to the solenoid 36, and a rotary solenoid, an electric cylinder, or the like can be used. Further, the plunger 37 of the solenoid 36 and the link stopper 38 may be integrated. Further, the plunger 37 itself of the solenoid 36 can be used as a link stopper. In the above embodiment, the shift lock link 32 is held in the locked position by the lock pin 24 of the detent rod 23 of the detent mechanism 22 in the P range of the shift lever 15. The shift lock link 32 may be held in the locked position by the engagement between the stop portion 50 and the engaging portion 52. Further, instead of the lock side engagement means, a dedicated holding means for holding the shift lock link 32 in the lock position may be provided. In the above-described embodiment, the shift lock link 32 is moved from the unlock position to the lock position using the return operation of the lock pin 24 of the detent rod 23 of the detent mechanism 22 in the P range of the shift lever 15. However, dedicated position changing means for moving the shift lock link 32 from the unlock position to the lock position may be provided. In the above embodiment, the unlock side engaging means for stopping the shift lock link 32 moved in the unlock direction by the link spring 34 at the unlock position by the link stopper 38 is provided. Instead of the engaging means, a stopper member for stopping the shift lock link 32 at the unlock position may be provided on the base bracket 12.

DESCRIPTION OF SYMBOLS 10 ... Shift lever apparatus 15 ... Shift lever 22 ... Detent mechanism 23 ... Detent rod (operation member)
24 ... Lock pin 26 ... Shift button (Detent release button)
30 ... Shift lock device 32 ... Shift lock link (shift lock member)
34 ... Link spring (elastic member)
36 ... Solenoid (actuator)
38 ... Link stopper (stopper member)
50 ... engaging portion 52 ... engaging portion

Claims (5)

Automatic shift provided with a shift lever that selects one shift range of a plurality of shift ranges including the P range, and a detent mechanism that holds the shift lever in the P range and releases the hold by operating a detent release button A shift lock device provided in a machine shift lever device for restricting the release operation of the detent mechanism holding the shift lever in the P range and releasing the restriction of the release operation of the detent mechanism in conjunction with a brake operation of a vehicle Because
A shift lock member movably provided between a lock position for restricting the release operation of the actuating member of the detent mechanism and an unlock position for releasing the restriction;
An elastic member for urging the shift lock member in the unlocking direction;
An actuator having a plunger interlocked with a brake operation of the vehicle;
A shift lock device, comprising: a restriction member that restricts movement of the shift lock member in the unlock direction by a plunger of the actuator; and a stopper member that is moved to an allowable position that permits the movement. The shift lock device according to claim 1,
Lock side engagement means is provided between the shift lock member and the stopper member,
The lock-side engagement means includes a locking portion provided on one member, and an engagement portion provided on the other member and detachably provided on the locking portion,
The shift lock device is characterized in that movement of the shift lock member in the unlocking direction is restricted by the engagement between the locking portion and the engagement portion. The shift lock device according to claim 1 or 2,
In the P range of the shift lever, the shift lock device is configured such that the shift lock member is held in a locked position by an operating member of the detent mechanism. The shift lock device according to claim 3,
In the P range of the shift lever, the shift lock device is configured to move the shift lock member from the unlock position to the lock position using the return operation of the operating member of the detent mechanism. The shift lock device according to any one of claims 1 to 4,
The shift lock device, wherein the shift lock member moved in the unlocking direction by the elastic member is stopped at the unlock position by the stopper member.

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