JPH0771151A - Actuator for door lock device - Google Patents

Abstract

PURPOSE:To certainly actuate a door lock device by normally rotating a motor to change over a door into a locked state, and after the motor is stopped once, normally rotating it again to make the door a superlocked state by a super lock mechanism. CONSTITUTION:When a motor 33 is normally rotated to turn a rotary member 35 counterclockwise, an actuating projection 45 turns a knob driving lever 54 clockwise to make a locking mechanism a locked state. Next the supply of electricity to the motor 33 is shut off, and the rotary member 35 is returned to a neutral position by a neutralizing returning spring. When the rotary member 35 is turned counterclockwise again, an actuating lever 56 turns a changing lever 67 clockwise to displace the engaging pin 53 of a bending lever for actuating a super lock mechanism to make a door a superlocked state. In addition, when the rotary member 35 is turned clockwise by the motor 33, the changing lever 67 is turned counterclockwise to displace the pin 53 for releasing the super lock mechanism to release the superlocked state.

Description

Detailed Description of the Invention

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to an actuator for a door lock device provided with a super lock mechanism. The super lock mechanism in the present invention means an inner lock member of a door (corresponding to a so-called sill knob button).
A mechanism that does not unlock even if you unlock.

[0002]

2. Description of the Related Art In the conventionally known US Pat. No. 4,978,154, a screw shaft 2 is axially moved with respect to a screw shaft 2 (hereinafter, the reference numerals in this section and the following section are those described in the cited specification) by the forward and reverse rotations of a motor. A top 3 that moves back and forth, and a moving member 4 that elastically frictionally engages the outer periphery of the top 3 and moves back and forth together with the top 3.
The moving member 4 is connected to the lock mechanism of the door lock device.
Is connected to the sill knob drive lever 14 that is displaced to the lock side when the vehicle moves forward and to the unlock side when the vehicle is moved backward, and to the sill knob drive lever 14 and the idling mechanism by the displacement of the engaging pin 30 ( Silknob interlocking lever 17 connected via a super lock mechanism)
And a switching lever 20 for displacing the engagement pin 30, and when the top 3 further moves forward after displacing the moving member 4 to the lock position, the switching lever 20 is displaced to operate the idling mechanism. The actuator for the door lock device is described.

[0003]

In the above-mentioned known example, when the top 3 screwed onto the shaft 2 advances in the axial direction of the shaft 2, the moving member 4 is in the lock position on the way, and when it further advances, the moving member 4 moves. The elastic engagement with is released, and only the top 3 moves independently to displace the switching lever 20. In other words, if the top 3 is stopped midway, the lock device can be switched to the locked state without the super lock. In the publicly known example, for this purpose, a sensor is provided in the vicinity of the shaft 2 to detect when the top 3 advances halfway, and the motor is stopped by this sensor. However, in the unlikely event that the sensor fails, the top 3 moves forward without stopping at the lock position on the way, so that when the motor is moved, there is a problem that the lock is always brought into the super lock.

[0004]

Therefore, according to the present invention, the elasticity of the neutral return spring 38 holds the motor 3 in the neutral position.
A rotary member 35 that rotates forward and reverse by the power of No. 3, a sill knob drive lever 54 that is connected to a lock mechanism of a door lock device and that is displaced to the lock side when the rotary member 35 rotates normally and to the unlock side when it rotates reversely; A sill knob interlocking lever 47 connected to the inner lock member 14 of the sill knob driving lever 54 and an oscillating mechanism for displacement of the engagement pin 53, and a switching lever 67 displacing the engagement pin 53. , An operating lever 56 elastically fixed to a predetermined position by the elastic force of a holding spring 57 with respect to the sill knob drive lever 54, and when the rotating member 35 normally rotates from the neutral position by the power of the motor 33, The sill knob drive lever 54 is displaced to the lock side to switch the lock mechanism to the lock state, but the operating lever 56 is held at the holding position. Not displaced against the elastic force of Ne 57, the motor 33 is the rotating member 35 the locking mechanism is turned switched and off the lock state wherein the neutral return spring 3
8 returns to the neutral position by the elastic force of the holding spring 57, and the operating lever 56 returns to the predetermined position by the elastic force of the holding spring 57. Then, when the rotating member 35 rotates forward again, the operating lever 56 moves the elastic force of the holding spring 57. The door lock device actuator that displaces the engaging pin 53 to a position where the switching lever 67 is displaced to displace the engagement lever 53 to a position where the idle vibration mechanism is operated, and the rotation lever 35 reversely rotates the switching lever. 67 to engage with the engagement pin 5
3 is a door lock device actuator in which a super lock release step portion 44 for releasing the idle vibration mechanism of 3 is formed.

[0005]

An embodiment of the present invention will be described with reference to the drawings.
Reference numeral 1 denotes a body of a lock device attached to a door, and on its front side, as shown in FIG. 2, a latch 3 engaged with a striker 2 fixed to the vehicle body and a latch 3 are engaged to prevent the reverse rotation thereof. A known latch mechanism consisting of the ratchet 4 is provided. On the back side of the body 1, as shown in FIG. 1, one side base of the open lever 5 in the left-right direction is fixed by a shaft 6, and the other end of the open lever 5 is vertically opened. The upper end of the link 7 is superposed, and the bent portion 9 at the lower end of the rod 8 which is connected to the door opening handle 10 of the door is inserted into the superposed portion to be axially coupled.

Reference numeral 11 denotes an inner lock lever (see FIG. 12) which is axially stopped by a shaft 12 at the lower right position on the back side of the body 1, and is operated by an actuator 13 or an inner lock member 14 (sill knob) described later. Axis 12
Rotate around to switch between locked and unlocked positions. One end of the horizontal connecting rod 15 (FIG. 13) is axially fixed to the inner lock lever 11 by a pin 16, and the other end of the horizontal connecting rod 15 is axially fixed to the lower end of the open link 7 by a pin 17. When the inner lock lever 11 is rotated to the left and right, the open link 7 swings left and right around the bent portion 9 via the horizontal connecting rod 15, and the contact portion 20 formed at the lower end of the open link 7 is locked. Switch between position and unlock position.

In FIG. 2, reference numeral 18 denotes a ratchet pin formed at the end of the ratchet 4, and the arcuate hole 19 formed in the body 1 projects further toward the back side of the body 1.
The abutting portion 20 of the open link 7 faces the ratchet pin 18 in the unlocked position (FIG. 1), and when the open link 7 is moved downward by the opening operation of the door opening handle 10, the ratchet pin 18 is pushed down. The ratchet 4 is disengaged from the latch 3, but at the lock position moved to the right from the unlock position, the ratchet 4 is displaced to the right from the ratchet pin 18, and even if the open link 7 moves downward, the ratchet 4 is missed and the door cannot be opened.

An outer lock lever 21 is provided at a lower portion of the body 1 to the left of the inner lock lever 11.
And the outer lock lever 21 is fixed to the body 1 by a shaft 22. In FIG. 1, the lower end of the rod 24 reaching the key cylinder 23 is connected to the left end portion of the outer lock lever 21. Outer lock lever 21
A circular arc groove 25 centering on the shaft 22 is formed in the circular groove 25, and a projection 26 integrally formed with the lateral connecting rod 15 is engaged with the circular arc groove 25 through a lost motion. The outer lock lever 21 is formed of a thick synthetic resin, and the arcuate groove 25 is formed by being recessed toward the inner surface side. When the outer lock lever 21 is rotated to the right by the key cylinder 23 in the unlocked state of FIG. 1, the left wall of the arc groove 25 pushes the protrusion 26 to move the lateral connecting rod 15 to the right, and the open link 7 is centered on the bent portion 9. The contact portion 20 rotates to the ratchet pin 1
The inner lock member 14 moves to the lock position as the inner lock lever 11 also rotates to the right by separating from 8 to the right.

An engaging hole 27 is formed in the right end portion of the inner lock lever 11, and a protruding end portion 29 of an L-shaped intermediate lever 28 (FIGS. 3 and 7) is engaged with the engaging hole 27. The intermediate lever 28 is fixed to the lock output shaft 30 of the actuator 13.

Reference numeral 47 denotes a sill knob interlocking lever (FIG. 8) rotatably attached to the lock output shaft 30, and a rod 48 reaching the inside lock member 14 is locked to the tip end side of the sill knob interlocking lever 47. The sill knob interlocking lever 47 has an engaging hole 4 extending in a radial direction with respect to the lock output shaft 30.
9 and an L-shaped hole 51 composed of the idle groove 50 extending in the circumferential direction of the lock output shaft 30. An elongated hole 52 is formed in the intermediate lever 28 so as to overlap with the engaging hole 49, and an engaging pin 53 is inserted into the L-shaped hole 51 and the elongated hole 52. The engagement pin 53 is switched by the power of the actuator 13 between the outer end position and the inner end position of the elongated hole 52 (movement by the actuator 13 will be described later), and when it is at the outer end position, the engagement pin 53 of the inner lock member 14 moves. When the sill knob interlocking lever 47 is rotated by an operation, the intermediate lever 28 is also rotated by the engagement with the engagement pin 53 to switch the locked state as described above. However, when the intermediate lever 28 is displaced to the inner end position of the elongated hole 52, Even if the interlocking lever 47 rotates, the engagement pin 5
No. 3 is an idling just by moving in the idling groove 50,
The intermediate lever 28 does not rotate, and the locked state cannot be switched. This idling mechanism is the main point of the super lock of the present invention.

Cases 31 and 3 of the actuator 13
A motor 33 is mounted inside the motor 2, and a worm 34 is fixed to the rotary shaft of the motor 33. Reference numeral 35 is a substantially disk-shaped rotating member that is rotatably fixed to the cases 31 and 32 by a shaft 36 in the left-right direction, and a fan-shaped gear portion 37 that meshes with the worm 34 is formed on the outer peripheral portion thereof. An annular groove 39 centered on the shaft 36 is formed on the left side surface of the rotating member 35 (FIGS. 4 and 14), and the neutral return spring 38 is housed in the annular groove 39. A concentric arc groove 40 is formed on the outer circumference of the annular groove 39, and a projection 41 integrally projected from the case 32 is engaged with the arc groove 40. Outside the center of the arc groove 40,
The protrusion 42 is integrally formed, and both legs 43 of the neutral return spring 38 are engaged with the protrusion 42 and the protrusion 41. The rotation member 35 moves from the state shown in FIG.
When 1 rotates in both left and right directions until it comes into contact with both ends of the arc groove 40 and the motor 33 is turned off, the neutral return spring 38 returns to the position shown in FIG. Reference numeral 44 denotes a super lock releasing step formed on the left side surface of the rotating member 35 (FIG. 1).
4). As shown in FIG. 5, a pair of left and right actuating protrusions 45 and a releasing protrusion 46 are formed on the right side surface of the rotating member 35.

At the upper position inside the cases 31 and 32,
A sill knob drive lever 54 is provided as shown in FIG. The base portion (upper portion) of the sill knob driving lever 54 is the lock output shaft 3
It is fixed to 0 and the operating lever 56 is attached to the sill knob drive lever 54 by a stepped pin 55 (FIG. 4) at an intermediate position in the longitudinal direction.
Rotatably attach the shaft. A holding spring 57 is wound around the outer periphery of the protruding portion of the stepped pin 55 (see FIGS.
6) The both legs 58 of the holding spring 57 are engaged with the protrusion 59 integrally formed on the left side surface of the operating lever 56 and the lock output shaft 30. As a result, the operating lever 56 is
The sill knob drive lever 54 is elastically fixed by the elastic force of the holding spring 57. The sill knob driving lever 54
A predetermined gap 62 is formed between the front end 60 of the rotary lever 35 and the front end 61 of the operating lever 56, and the operating protrusion 45 of the rotating member 35 in the neutral position is exposed to the gap 62 (see FIG. 5). When the rotating member 35 rotates counterclockwise, the operating protrusion 45 is inserted between the sill knob driving lever 54 and the operating lever 56.

Reference numeral 63 denotes a super lock switching shaft which is provided in the vicinity of the lock output shaft 30 and which is parallel to the output shaft 30. One end of the super lock switching shaft 63 penetrates the case 32 and projects outward to the right as shown in FIG. Then, the base portion of the intermediate lever 64 (FIG. 10) is fixed to the portion protruding to the right. Intermediate lever 6
The tip of 4 faces the axis of the lock output shaft 30,
The base of a bending lever 65 (FIG. 1) bent in a substantially L shape at the tip of the intermediate lever 64 is fixed by a pin 66. The engaging pin 53 is integrally formed at the tip of the bending lever 65.

A base portion of a switching lever 67 is fixed to the super lock switching shaft 63. The switching lever 67 is shown in FIG.
As described above, a part of the fan shape is made to project long, and a projection 68 that projects rightward in the axial direction is formed at the tip. The protrusion 68 is formed at a position facing the other end leg portion 69 of the operating lever 56, and when the operating lever 56 largely rotates to the right, the other end leg portion 69 engages with the protrusion 68 to rotate the switching lever 67 to the right, When the switching lever 67 rotates to the right, the super lock switching shaft 63 also rotates to the right, and the intermediate lever 64 passes through the switching shaft 63.
3 also rotates to the right, whereby the bending lever 65 is displaced in the direction of arrow a in FIG. 3, and the engaging pin 53 formed integrally with the tip of the bending lever 65 is moved from the outer end position of the elongated hole 52 to the inner end position. Displace it and put it in the super lock state. An engaging protrusion 70 that protrudes toward the rotating member 35 is formed at the lower end of the fan-shaped portion of the switching lever 67. When the switching lever 67 is rotated clockwise from the state of FIG. 5 to the super lock position, the engaging protrusion 70 is formed on the left side surface of the rotating member 35 as shown in FIG. 18) and the position on the rotation locus of FIG.
In this state, when the rotating member 35 rotates to the right, the super-lock releasing step 44 engages with the engaging protrusion 70 and pushes up the switching lever 67 to rotate it to the left.

[0015]

In the unlocked state, the abutment piece 20 of the open link 7 faces the upper portion of the ratchet pin 18 as shown in FIG. 1, and the engagement pin 53 for the super lock is the length of the intermediate lever 28. Located at the outer end of the hole 52, the sill knob interlocking lever 47 and the intermediate lever 28 are integrally connected.

In this state, when the key cylinder 23 is locked and rotated, the outer lock lever 21 rotates right in FIG. 1 and the left wall of the circular arc groove 25 engages with the projection 26 and pushes it, so that the lateral connecting rod is pushed. By sliding 15 to the right, the contact piece 20 of the open link 7 is disengaged from the ratchet pin 18 and displaced to the lock position. At the same time, the inner lock lever 11 connected to the lateral connecting rod 15 by the pin 16 is also pushed, and the shaft 1
2 is rotated clockwise about 2, and the intermediate lever 28 in which the projecting end 29 is engaged with the engaging hole 27 of the inner lock lever 11
3 rotates to the right in FIG.
Since the sill knob interlocking lever 47 engaged by 3 also rotates to the right, the inner lock member 14 is also displaced to the lock position via the rod 48.

When the inner lock member 14 is locked, the sill knob interlocking lever 47 rotates clockwise through the rod 48 in FIGS. 1 and 3, and engages with the sill knob interlocking lever 47 by the action of the engaging pin 53. The intermediate lever 28 also rotates to the right, the inner lock lever 11 engaged with the protruding end 29 of the intermediate lever 28 rotates to the right in FIG. 1, and the open link 7 is switched to the lock position via the lateral connecting rod 15. .

When the actuator 13 is switched from the unlocked state to the locked state, the motor 33 is normally rotated to rotate the rotating member 35 counterclockwise in FIG. Then, the operating protrusion 45 of the rotating member 35 enters into the gap 62 between the tip 60 of the sill knob driving lever 54 and the tip 61 of the operating lever 56, and rotates the sill knob driving lever 54 to the right as shown in FIG. The lock output shaft 30 integrated with the sill knob drive lever 54 is rotated clockwise. Lock output shaft 3
Since the intermediate lever 28 is fixed to the protruding end of 0, the intermediate lever 28 rotates clockwise in FIG. 3, and the inner lock lever 11 with which the protruding end portion 29 of the intermediate lever 28 is engaged in FIG. When the inner lock lever 11 is rotated clockwise, the open link 7 is switched to the lock position via the lateral connecting rod 15 by the clockwise rotation of the inner lock lever 11. At the same time, the intermediate lever 2
The right rotation of 8 also rotates the sill knob interlocking lever 47 right through the engagement pin 53, and switches the inner lock member 14 to the lock position.

As described above, the rotating member 35 is connected to the motor 33.
When the sill knob drive lever 54 is rotated to the left by, the operating lever 56 does not rotate much due to the action of the operating protrusion 45 that has entered the gap 62.
5, the gap 62 becomes large. When the rotating member 35 rotates counterclockwise to switch to the locked state as described above, the power supply to the motor 33 is automatically cut off, and the rotating member 35 is neutralized by the elastic force of the neutral return spring 38 (FIG. 6). Return to position. At this time, the actuating protrusion 45 of the rotating member 35 pushes the tip 61 of the actuating lever 56 slightly to the left side, and then comes off the tip 61, and the actuating lever 56 released from the engagement with the actuating protrusion 45 has the elastic force of the holding spring 57. Thus, the sill knob drive lever 54 that has been moved earlier is rotated clockwise so as to follow it, and the state shown in FIG. 16 is reached, and the switching to the lock by the actuator 13 is completed.

To switch to the super lock, see FIG.
From this state, the motor 33 is energized again to rotate the rotating member 35 counterclockwise. Then, in FIG. 16, since the tip 61 of the actuating lever 56 is within the rotation locus of the actuating protrusion 45, when the rotating member 35 rotates counterclockwise, the actuating protrusion 45 engages with the outside of the tip 61 to move the actuating lever 56 to the right. It comes to rotate. When the operating lever 56 rotates clockwise, the other end leg portion 69 of the operating lever 56 engages with the protrusion 68 of the switching lever 67,
The switching lever 67 is rotated to the right, and when the switching lever 67 is rotated to the right, the super lock switching shaft 63 is also rotated to the right as shown in FIG. 17. The intermediate lever 64 fixed to the protruding portion of the super lock switching shaft 63 is shown in FIG. Rotate clockwise and bend lever 6
5 is moved in the direction of arrow a to displace the engagement pin 53 of the bending lever 65 from the outer end position of the elongated hole 52 of the intermediate lever 28 to the inner end position, and the super lock state is established. Engagement pin 5
When 3 reaches the inner end position of the long hole 52, the power supply to the motor 33 is cut off, the rotating member 35 is returned to the neutral position by the elastic force of the spring 38, and the operating lever 56 is moved to the predetermined position by the elastic force of the holding spring 57. Return (Fig. 18).

When the engagement pin 53 is located at the inner end (lower end) of the elongated hole 52 and is in a super lock state, even if the inner lock member 14 is directly unlocked and rotated, the engagement pin 53 becomes L.
Since the vibration is generated only by moving in the empty vibration groove 50 of the mold hole 51, the rotation of the interlocking lever 47 is not transmitted to the intermediate lever 28, the switching to the unlocked state is impossible, and the door cannot be opened. .

To release the super lock, the motor 33 is energized to rotate the rotating member 35 clockwise in FIG. Then, the release protrusion 46 moves the sill knob drive lever 5
4 is engaged with the outside of the tip 60 of the sill knob drive lever 5
4 is rotated counterclockwise together with the lock output shaft 30, and the super-lock release step 44 causes the engagement protrusion 7 of the switching lever 67 to move.
0 is also engaged to rotate the switching lever 67 together with the super lock switching shaft 63 to the left. When the output shaft 30 rotates counterclockwise, the intermediate lever 28 fixed to the protruding end rotates left in FIG. 3, and the inner lock lever 11 engaged with the protruding end 29 of the intermediate lever 28 rotates left in FIG. The open link 7 is switched to the unlock position via the rod 15. When the super lock switching shaft 63 rotates counterclockwise, the intermediate lever 64 fixed to the protruding end of the switching shaft 63
In FIG. 3, the bending lever 65 is rotated counterclockwise in FIG. 3 to move the engaging pin 53 to the outer end position (upper end) of the elongated hole 52. As a result, it is possible to release the super lock and switch to the unlock at the same time.

[0023]

As described above, according to the present invention, the rotating member 35, which is held in the neutral position by the elastic force of the neutral return spring 38 and rotates forward and reverse by the power of the motor 33, is connected to the lock mechanism of the door lock device. The sill knob drive lever 54 is displaced to the lock side when the rotating member 35 is normally rotated and is displaced to the unlock side when the rotating member 35 is rotated reversely. A sill knob interlocking lever 47 connected via an idle vibration mechanism, a switching lever 67 for displacing the engaging pin 53, and a sill knob driving lever 54 are elastically fixed at a predetermined position by a resilient force of a holding spring 57. When the rotating member 35 is normally rotated from the neutral position by the power of the motor 33, the sill knob drive lever is 54 is displaced to the lock side to switch the lock mechanism to the locked state, but the operating lever 56 is not displaced against the elastic force of the holding spring 57, and the motor 33 switches the lock mechanism to the locked state. When turned off, the rotating member 35 returns to the neutral position by the elastic force of the neutral return spring 38, and the operating lever 56 returns to the predetermined position by the elastic force of the holding spring 57.
After that, when the rotating member 35 is normally rotated again, the operating lever 56 is displaced against the elastic force of the holding spring 57 to displace the switching lever 67 and move the engaging pin 53 to a position for operating the idle vibration mechanism. An actuator for a door lock device to be displaced, and a door lock in which the rotation member 35 is formed with a super lock release stepped portion 44 that engages with the switching lever 67 when it is reversed and releases the idle vibration mechanism by the engagement pin 53. Since this is an actuator for the apparatus, if the forward / reverse rotation motor 33 is locked by the forward rotation of the rotating member 35, the forward / reverse rotation motor 33 is automatically de-energized and automatically stopped. When it is stopped, the rotating member 35 returns to its original state by the elastic force of the spring 38, and when the forward / reverse rotation motor 33 is energized again for normal rotation, the super-lock machine Since infrasound mechanism and operates the is, without a trouble occurs, such as the known example,
The effect is that the operation is reliable and the configuration is simple.

[Brief description of drawings]

FIG. 1 is a partially cutaway rear view of a locking device.

FIG. 2 is a front view of a lock body.

FIG. 3 is a schematic view showing an idling mechanism.

FIG. 4 is a developed sectional view of an actuator.

FIG. 5 is a right side view of the inside of the actuator.

FIG. 6 is a left side view of the inside of the actuator.

FIG. 7 is a plan view of the intermediate lever.

FIG. 8 is a plan view of a sill knob interlocking lever.

FIG. 9 is a plan view of an operating lever.

FIG. 10 is a plan view of the intermediate lever.

FIG. 11 is a plan view of a bending lever.

FIG. 12 is a plan view of an inner lock lever.

FIG. 13 is a plan view of a horizontal connecting rod.

FIG. 14 is a perspective view of a rotating member.

FIG. 15 is an operation diagram when the rotating member is locked and rotated.

FIG. 16 is an operation diagram after completion of switching to the lock.

FIG. 17 is an operation diagram when the rotating member is again locked and rotated.

FIG. 18 is an operation diagram after completion of switching to super lock.

[Explanation of symbols]

1 ... Body, 2 ... Strike, 3 ... Latch, 4 ... Ratchet, 5 ... Open lever, 6 ... Shaft, 7 ... Open link, 8 ... Rod, 9 ... Bend part, 10 ... Door opening handle, 1
DESCRIPTION OF SYMBOLS 1 ... Inner lock lever, 12 ... Shaft, 13 ... Actuator, 14 ... Inner lock member, 15 ... Horizontal connecting rod, 16
... pin, 17 ... pin, 18 ... ratchet pin, 19 ... arc hole, 20 ... contact piece, 21 ... outer lock lever, 2
2 ... Shaft, 23 ... Key cylinder, 24 ... Rod, 25 ... Arc groove, 26 ... Projection, 27 ... Engagement hole, 28 ... Intermediate lever,
29 ... Monopod, 30 ... Lock output shaft, 31 ... Case, 32
... case, 33 ... motor, 34 ... worm, 35 ... rotating member, 36 ... shaft, 37 ... gear section, 38 ... neutral return spring,
39 ... Annular groove, 40 ... Arc groove, 41 ... Protrusion, 42 ... Protrusion, 43 ... Both legs, 44 ... Super lock release step portion, 45
... operating projection, 46 ... release projection, 47 ... sill knob interlocking lever, 48 ... rod, 49 ... engaging hole, 50 ... idle groove, 51
... L-shaped hole, 52 ... Long hole, 53 ... Engaging pin, 54 ... Silv knob drive lever, 55 ... Stepped pin, 56 ... Actuating lever, 5
7 ... Retaining spring, 58 ... Both legs, 59 ... Protrusion, 60 ... Tip,
61 ... Tip, 62 ... Gap, 63 ... Super lock switching shaft, 64 ... Intermediate lever, 65 ... Bending lever, 66 ... Pin, 67 ... Switching lever, 68 ... Projection, 69 ... Other end leg,
70 ... Engagement protrusion.

─────────────────────────────────────────────────── ───

[Procedure amendment]

[Submission date] May 12, 1994

[Procedure Amendment 1]

[Document name to be corrected] Drawing

[Correction target item name] All drawings

[Correction method] Change

[Correction content]

[Figure 1]

[Fig. 2]

[Figure 4]

[Figure 7]

[Figure 10]

FIG. 11

[Fig. 13]

[Figure 3]

[Figure 5]

[Figure 6]

[Figure 8]

[Figure 9]

[Fig. 12]

FIG. 14

FIG. 15

FIG. 16

FIG. 17

FIG. 18

Claims (2)

[Claims] 1. A rotating member 35 which is held in a neutral position by an elastic force of a neutral return spring 38 and which is normally and reversely rotated by a power of a motor 33, and a lock side which is connected to a lock mechanism of a door lock device when the rotating member 35 is normally rotated. And a sill knob drive lever 54 that is displaced to the unlock side when it is reversely rotated and is connected to the inner lock member 14 of the door and is also connected to the sill knob drive lever 54 through an idle vibration mechanism caused by the displacement of the engagement pin 53. A sill knob interlocking lever 47, a switching lever 67 for displacing the engagement pin 53, and an operating lever 56 elastically fixed to a predetermined position by the elastic force of a holding spring 57 with respect to the sill knob driving lever 54, When the rotary member 35 is normally rotated from the neutral position by the power of the motor 33, the sill knob drive lever 54
Moves to the lock side to switch the lock mechanism to the locked state, but the operating lever 56 does not move against the elastic force of the holding spring 57, and the motor 33 turns off when the lock mechanism switches to the locked state. And the rotating member 35
Is returned to the neutral position by the elastic force of the neutral return spring 38, the operating lever 56 is returned to the predetermined position by the elastic force of the holding spring 57, and then the operating lever 56 is rotated again when the rotating member 35 is normally rotated. Holding spring 5
An actuator for a door lock device that displaces the switching lever 67 by displacing it against the elasticity of No. 7 to displace the engagement pin 53 to a position where the idle vibration mechanism is operated. 2. The door lock according to claim 1, wherein the rotation member 35 is formed with a super lock release step portion 44 which engages with the switching lever 67 when being rotated in reverse and releases the idle vibration mechanism by the engagement pin 53. Actuator for equipment.