JP5351616B2 - Knob rotation lock structure of lever switch - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To provide an easy to assemble configuration for a lever switch having a light switch knob, a fixed knob and a fog switch knob adjacently arranged. <P>SOLUTION: The fog switch knob is locked by: having a slider block 40 for holding a lock piece 50 held in a slider block storing section of one knob; making the position of the slider block be variable in the axial direction according to the revolution of the knob; and engaging a lock piece with a lock hole of the knob that faces the lock piece when a light switch knob is at other than "headlight". The falling off of the lock piece is prevented by providing a slit 46 on a wall of a lock piece holding section 41 of the slider block, making the lock piece to include a projection 52 that slides in the slit and closing a top end of the slit. The slider block is also equipped with a projection 45 and slides in a groove in the slider block storing section but falling off is prevented by closing a top end of the groove. The assembly work without any possibility of falling off is carried out by having the lock piece and the slider block sub-assembled to the knob. <P>COPYRIGHT: (C)2011,JPO&amp;INPIT

Description

  The present invention relates to a knob rotation lock structure of a lever switch provided with two rotation knobs at a tip portion of a lever.

Various switches are installed in the vehicle, and many switches are concentrated on the steering column as so-called combination switches in order to improve operability. This combination switch is configured as a lever switch to which an operation lever is attached and various switches are operated by the operation.
For example, a rotary switch knob for switching light types of headlights and taillights and a rotary switch knob for flashing fog lights are arranged on the same axis.

Here, if the light type switching rotary switch knob (hereinafter referred to as the light switch knob) and the fog light flashing rotary switch knob (hereinafter referred to as the fog switch knob) can be operated independently of each other, the headlight will light up. There is a risk of forgetting to turn off the fog light when only the fog light is turned on.
For this reason, it has been proposed that the fog light can be turned on only under a headlight-on condition, and the fog light cannot be turned on when the headlight is off.
An example of such a lever switch is disclosed in Japanese Patent No. 3740316.

FIG. 14 shows a main part of the knob rotation lock structure disclosed in Japanese Patent No. 3740316.
In the vicinity of the end of the operation lever, the light switch knob 140, the fixed knob 130, and the fog switch knob 150 for the rear fog light are arranged adjacent to each other in the axial direction. In the drawing, an arrow Z indicates a rotation operation direction of the light switch knob 140 and the fog switch knob 150.
A lock release piece 161 is stored in the piece storage hole 128 in the fixed knob 130. The lock release piece 161 includes a lock surface 164 on the light switch knob 140 side, a non-lock surface 165 protruding to the light switch knob 140 side from the lock surface 164, and a slope 166 connecting the both surfaces 164 and 165.

A coil spring 167 is disposed between the lock release piece 161 and the bottom of the piece storage hole 128, and the lock release piece 161 is always in contact with the protrusion 122 extending from the light switch knob 140.
The fixing knob 130 includes an insertion hole 170 that penetrates the wall on the fog switch knob 150 side, and a protrusion 169 extends from the lower surface of the lock release piece 161 so that the inside of the insertion hole 170 can slide.
The fog switch knob 150 has a lock piece 172 disposed in the storage hole 171, and is constantly biased toward the fixed knob 130 by a coil spring 173. The lock piece 172 can be inserted into the insertion hole 170 of the fixed knob 130.

When the light switch knob 140 is in the “off” position and the fog switch knob 150 is in the “fog off” position, the headlight, tail light, and rear fog light are turned off.
In this state, the protrusion 122 of the light switch knob 140 is at the position P1 shown in FIG. 14A, and the lock release piece 161 is lighted until the lock surface 164 contacts the protrusion 122 by the urging force of the coil spring 167. Slide to the switch knob 140 side. As a result, the lock piece 172 is engaged with the insertion hole 170 in a state where the lock piece 172 is in contact with the protrusion 169 of the lock release piece 161 by the urging force of the coil spring 173.
Therefore, the fog switch knob 150 is locked with the lock piece 172 engaged with both the insertion hole 170 and the storage hole 171 and cannot be rotated.

  Next, when the light switch knob 140 is rotated from “off” to “tail lamp” from this state, the tail light is turned on, and the protrusion 122 moves to the P2 position as shown in FIG. Even in this state, since the lock piece 172 is locked, the rotation operation of the fog switch knob 150 is impossible.

Next, when the light switch knob 140 is rotated from the “tail lamp” to the “headlight” position, the headlight is turned on, and the protrusion 122 is in the P3 position as shown in FIG. Here, since the protrusion 122 presses the non-locking surface 165 of the lock release piece 161 against the coil springs 167 and 173, the lower surface of the protrusion 169 is substantially flush with the opposing surfaces of the fixing knob 130 and the fog switch knob 150. It becomes. As a result, the lock piece 172 is pushed out from the insertion hole 170, and the fog switch knob 150 can be operated.
Therefore, as shown in (d), the fog switch knob 150 can be rotated from the Z1 position of “fog off” to the Z2 position of “fog light”, and the rear fog light is turned on.

  Thereafter, the light switch knob 140 is returned to the “tail lamp” position, and even when the projection 122 reaches the P2 position where it abuts against the lock surface 164, as shown in FIG. The lock piece 172 housed in is only in contact with the opposing surface of the fixed knob 130, and can maintain the “fog light” position and keep the rear fog light on.

  As described above, in the lever switch disclosed in Japanese Patent No. 3740316, the fog switch knob 150 cannot be operated unless the light switch knob 140 is set to the “headlight” position, and unless the headlight is turned on. The rear fog light cannot be turned on. As a result, for example, the possibility of turning on only the rear fog light alone in a bright time zone that does not require lighting of the headlight and forgetting to turn it off later is eliminated.

Japanese Patent No. 3740316

By the way, in the conventional knob rotation lock structure, the lever switch is assembled in the following order.
First, the fog switch knob 150 is assembled at a predetermined position on the lever. Then, after the lock piece 172 is inserted into the accommodation hole 171 of the fog switch knob 150 together with the coil spring 173, the fixing knob 130 is attached to the fog switch knob 150 in an overlapping manner. Next, the lock release piece 161 is fitted into the piece storage hole 128 of the fixing knob 130 with the coil spring 167 sandwiched between the bottom. Thereafter, the light switch knob 140 is assembled.

  However, when the fixing knob 130 is attached to the fog switch knob 150 in an overlapping manner, the lock piece 172 is easily dropped from the storage hole 171 by the coil spring 173 extending in a free length. For this reason, although the lock piece 172 and the coil spring 173 that are hidden behind the fixing knob 130 are particularly small parts, the light switch knob 140 is similarly used, although it must be performed with care so as not to drop off. Unlike the relatively large-sized lock release piece 161 that is hidden on the back side, it is difficult to confirm and requires time, and there is a problem that the cost is increased due to an increase in the number of assembling steps.

The above-mentioned conventional example is related to prevention of forgetting to turn off the rear fog light, but it can be applied not only to the rear fog light but also between the front and side fog lights and other types of light switches. Similar problems remain when applied to switches of multiple devices other than lights.
Accordingly, an object of the present invention is to provide a knob rotation lock structure of a lever switch that is easy to assemble, paying attention to the above-mentioned conventional problems.

For this reason, the present invention
A first rotation knob, a fixed knob, and a second rotation knob are disposed adjacent to each other along the lever axial direction, and the first rotation knob has a position other than the first switch position and the first switch position. A second switch knob has a first switch position and a second switch position, and each of the second switch knobs corresponds to the first switch knob and the second switch knob. In the lever switch where the switch contact to be switched is
One of the fixed knob and the second rotary knob holds a slider block displaceable in the axial direction,
A cam mechanism that displaces the slider block in the axial direction according to the rotation is provided.
The slider block holds a lock piece biased in the protruding direction toward the other of the fixed knob or the second rotation knob,
The other of the fixed knob or the second rotation knob has a lock hole that can be engaged with a lock piece protruding from the slider block,
Between the lock piece and the slider block, there is provided means for preventing the lock piece from coming off,
The cam mechanism displaces the slider block to the other side of the fixed knob or the second rotary knob when the first rotary knob is at the first switch position of the first rotary knob, When the rotary knob is at a predetermined switch position of the first rotary knob, the slider block is displaced to the side away from the other of the fixed knob or the second rotary knob. When the knob is at the first switch position of the first rotation knob, the lock piece is engaged with the lock hole, and the first rotation knob is at the predetermined switch position of the first rotation knob. Sometimes the lock piece was released from engagement with the lock hole.

  According to the present invention, if the first rotation knob is not at the predetermined switch position, the second rotation knob is locked even if it is to be rotated from the first switch position of the second rotation knob. Therefore, the second switch position cannot be set, so that the possibility of forgetting to return the second rotary knob to the first switch position later is eliminated.

  And since the lock piece is secured to the slider block, when assembling the knobs to the lever sequentially, there is no risk of the lock piece falling off even if visual confirmation from the operator is impossible. It can be done in a short time and has the effect of reducing assembly man-hours.

It is a longitudinal cross-sectional view which shows the structure of the 1st Example of this invention. It is a disassembled perspective view of a 1st Example. It is the figure which looked at the knob in a 1st Example from the axial direction. It is an external appearance perspective view of the slider block in a 1st Example. It is a figure which shows the lock / cancel mechanism in 1st Example. It is explanatory drawing which shows the effect | action of the lock / cancellation mechanism in 1st Example. It is a longitudinal cross-sectional view which shows the structure of the 2nd Example of this invention. It is a disassembled perspective view of a 2nd Example. It is the figure which looked at the knob in a 2nd Example from the axial direction. It is an external appearance perspective view of the slider block in a 2nd Example. It is a figure which shows the lock / cancel mechanism in 2nd Example. It is explanatory drawing which shows the effect | action of the lock / cancellation mechanism in 2nd Example. It is explanatory drawing which shows the effect | action of the lock / cancellation mechanism in 2nd Example. It is a figure which shows a prior art example.

Hereinafter, a first embodiment in which the present invention is applied to an operation lever of a combination switch installed around a steering column of a vehicle will be described.
FIG. 1 is a longitudinal sectional view showing the configuration of the first embodiment, and FIG. 2 is an exploded perspective view.
The operating lever 1 has a triple structure including a second lever 3 and a third lever 4 on the inner side of the first lever 2 forming the outer cylinder over substantially the entire length excluding the tip (outer end).
The first lever 2 is supported by a switch case side member (not shown) fixed to the steering column, and the second lever 3 is formed integrally with the first lever 2. The operating lever 1 can be swung around a support point on the switch case side to displace the movable switch member in the switch case and perform switch operations such as turn signal and headlight irradiation direction switching. ing.

The second lever 3 extends to the tip of the outer end of the first lever 2.
The third lever 4 passes through the second lever 3, one end on the switch case side engages with a movable contact member (not shown), and the other end extends to the end of the outer end of the second lever 3. The third lever 4 is rotatable with respect to the second lever 3.
A light switch knob 10 as a first rotation knob is coupled to the distal end portion of the third lever 4 of the operation lever 1 via a connecting member 5, and a fixing knob 20 is coupled to the distal end portion of the second lever 3. A fog switch knob 30 as a second rotation knob is rotatably disposed on the second lever 3 between the fixed end of the first lever 2 and the fixed knob 20.
Thereby, the light switch knob 10, the fixing knob 20, and the fog switch knob 30 are arranged adjacent to each other sequentially from the tip of the operation lever 1.

When the light switch knob 10 is rotated, the third lever 4 is rotated with respect to the second lever 3, and a movable contact member (not shown) on the switch case side is operated to turn on and off the taillight and the headlight. Is switched.
In this embodiment, the light switch knob 10 is rotated in three positions: “off” (headlight and taillight off), “tail” (taillight on), and “headlight” (headlight and taillight on). Is set.

Near the tip of the first lever 2, a fixed contact board 6 is provided in a space between the second lever 3, and the movable contact 7 facing this is supported by the fog switch knob 30 and can turn. ing. These are omitted in FIG.
A wiring (not shown) from the fixed contact board 6 extends in the space between the first lever 2 and the second lever 3 in the direction of the support point on the switch case side. Accordingly, the fog light is switched on and off in accordance with the rotation of the fog switch knob 30. As the rotation position of the fog switch knob, two positions of “fog off” (fog light off) and “fog light” (fog light on) are set.

The outer periphery of the tip of the first lever 2 is cut out in a step shape to form a small diameter portion 2a.
In particular, as shown in FIG. 1, the fixing knob 20 includes, as a basic shape, an outer cylinder 21, a hub part 23 for fixing to the second lever 3, and a disk wall part 22 connecting the outer cylinder 21 and the hub part 23. Become. The outer cylinder 21 includes a small diameter portion 21a on the fog switch knob 30 side.
The light switch knob 10 has a bottomed cylindrical shape, and is provided with a small-diameter portion 10a that enters the inner diameter side of the outer cylinder 21 of the fixed knob 20 at the opening, and the outer peripheral surface of the light switch knob 10 and the fixed knob 20 (outer cylinder). 21) The outer peripheral surface is smoothly continuous.

The fog switch knob 30 has a thick disk shape as a basic shape, includes an extension boss portion that extends to the vicinity of the fixed contact plate 6 and supports the movable contact 7, and a center hole that can slide (rotate) on the second lever 3. have. In addition, a projecting portion that surrounds the small diameter portion 21 a of the fixed knob 20 and a projecting portion that surrounds the small diameter portion 2 a of the first lever 2 are provided at both ends of the outer peripheral portion. For easy operation, the outer peripheral surface of the fog switch knob 30 slightly protrudes from the fixing knob 20 and the first lever 2 on both axial sides.
The axis of the fixed knob 20 coincides with the axes of the light switch knob 10 and the fog switch knob 30.

A lock / cancel mechanism for the fog switch knob 30 using the slider block 40 is formed between the light switch knob 10, the fixed knob 20, and the fog switch knob 30. The lock / cancel mechanism will be described in detail below.
FIG. 3A is a view of the fixed knob 20 as viewed from the light switch knob 10 side.
The fixed knob 20 is provided with a through-hole 25 through which the cancel lever 12 extending from the light switch knob 10 passes, in an arc shape centering on the axis of the fixed knob 20.
In addition, a lock hole 27 is provided on the back surface (side facing the fog switch knob 30).

FIG. 3B is a view of the fog switch knob 30 as viewed from the fixed knob 20 side.
A slider block housing portion 35 is formed that opens to the end surface on the fixed knob 20 side over a predetermined length range in the circumferential direction of the fog switch knob 30. As shown in FIG. 5B described later, the slider block storage portion 35 has a flat bottom surface, and a spring support protrusion 37 described later is provided on the bottom surface. At both ends in the circumferential direction of the slider block storage portion 35, axial grooves 36 and 36 closed by the opening surface of the slider block storage portion 35 are formed. FIG. 3B shows the groove 36 in a cross section only at one end side.

FIG. 4 is an external perspective view showing the slider block 40 together with the lock piece 50, the return spring 48, and the spring 54.
The slider block 40 is a resin block having an arc shape as a whole, and includes a piece holding portion 41 for receiving and holding the lock piece 50 at one end in the circumferential direction. A portion 42 (see FIG. 5) and a cam surface 43 are provided.
The cam surface 43 is retracted from the upper surface in the axial direction, that is, offset downward, and the wall surfaces 44 a and 44 b at both ends along the circumferential direction of the arc, that is, the direction in which the cancel lever 12 moves on the cam surface 43. It is sandwiched between.
The cam surface 43 includes a low region 43a on the wall surface 44a (spring storage portion 42 side), a high region 43c on the wall surface 44b side on the other end, and an inclined region 43b connecting them.

The bottom surface of the slider block 40 is parallel to the top surface and flat. The piece holding part 41 opens on the top surface, and the spring storage part 42 opens on the bottom surface.
Here, the side facing the fixing knob 20 in the state of being housed and incorporated in the slider block housing portion 35 will be described as the upper side, and the opposite side as the lower side.

The outer surface of one end in the circumferential direction of the slider block 40 (on the piece holding portion 41 side) is a flat surface parallel to the axial direction, but has a claw 45 having an inclined surface on the lower side. The outer surface of the other end in the circumferential direction of the slider block 40 (cam surface 43 side) is the same, and has a claw 45. After the slider block 40 is assembled by pushing the bottom surface first from the fixed knob 20 side into the slider block storage portion 35 of the fog switch knob 30, the pawl 45 slides in the groove 36 of the slider block storage portion 35, and the groove Since 36 is closed on the opening surface side of the slider block storage portion 35, the slider block 40 is prevented from coming off.
The height of the slider block 40 in the axial direction (distance between the top surface and the bottom surface) is smaller than the depth of the slider block storage portion 35 so that a predetermined slide amount can be obtained within the depth range of the slider block storage portion 35. Is set.

The piece holding part 41 is formed as a hole having a rectangular cross section perpendicular to the axis, and slits 46 extending in the vertical direction are formed on the inner and outer peripheral walls.
The lock piece 50 has a rectangular cross section corresponding to the hole of the piece holding portion 41 and is slidably held by the piece holding portion 41. The tip of the slider block 40 facing outward from the upper surface of the slider block 40 extends in the circumferential direction of the slider block. A smooth arc shape may be formed in the plane along, or a spherical surface may be sufficient.

Protrusions 52 are provided on the inner peripheral side and outer peripheral side surfaces of the lock piece 50. After the lock piece 50 is pushed into the piece holding part 41 and assembled, the protrusion 52 slides on the slit 46 of the piece holding part. The sliding range of the protrusion 52 is regulated by the upper end of the slit 46 so as to prevent the lock piece 50 from coming off.
Since the lock piece 50 has a rectangular cross section and a rectangular parallelepiped shape as described above, the protrusion 52 automatically fits into the slit 46 when pressed in accordance with the hole shape of the piece holding portion 41. Position alignment of 52 and the slit 46 is easy.
A spring 54 is provided between the lock piece 50 and the bottom wall of the piece holding portion 41, whereby the lock piece 50 is urged in a direction in which its tip protrudes from the upper surface of the slider block 40.

(A) of FIG. 5 is the figure which looked at the state which accommodated the slider block 40 in the slider block accommodating part 35 from the fixed knob 20 side, (b) is AA section sectional drawing along the circumferential direction in (a). is there.
A return spring 48 disposed in the spring accommodating portion 42 of the slider block 40 has one end abutted against the upper wall of the spring accommodating portion 42 and the other end positioned at the spring support protrusion 37 on the bottom surface of the slider block accommodating portion 35. The slider block 40 is biased in a direction in which the slider block 40 is separated from the bottom surface of the slider block storage unit 35.
The slider block 40 is urged so that its claws 45 slide in the grooves 36 at both ends in the circumferential direction of the slider block storage portion 35 and protrude from the end face of the fog switch knob 30 on the fixed knob 20 side. Since the opening portion side of the storage portion 35 is closed as described above, it does not fall off from the fog switch knob 30.

The lock piece 50 is urged by the spring 54 and protrudes from the upper surface of the slider block 40. As described above, the protrusion 52 is prevented from coming off at the end of the slit 46 of the piece holding portion 41 so that the lock piece 50 is removed from the slider block 40. It will not drop out.
Accordingly, with respect to the fog switch knob 30, first, the lock piece 50 (and the spring 54) is assembled to the slider block 40 to be a primary subassembly, and this primary subassembly is assembled to the fog switch knob 30 to be a secondary subassembly. it can.

The through-hole 25 of the fixed knob 20 is such that the cancel lever 12 can be pivoted in the penetrating state without any trouble while the light switch knob 10 is pivoted from “OFF” through “tail” to the “headlight” position. The length in the circumferential direction is set.
The position of the slider block storage portion 35 in the fog switch knob 30 is such that the cam surface 43 of the slider block 40 stored in the slider block storage portion 35 corresponds to the circumferential length of the through long hole 25 of the fixed knob 20. Thus, the cancel lever 12 is set so as to be movable between one end in the circumferential direction of the cam surface 43 and the other end (that is, between the wall surfaces 44a and 44b) in response to the rotation of the light switch knob 10. .

  A lock hole 27 is provided at a position facing the lock piece 50 when the fog switch knob 30 is in the “fog off” position on the surface of the fixed knob 20 facing the fog switch knob 30. The tip of the lock piece 50 protruding from the lock hole 27 can be engaged with the lock hole 27.

For attachment to each lever, first, the fog switch knob 30 which is a secondary subassembly by incorporating the slider block 40 is attached to the second lever 3 so as to be rotatable, and then the fixing knob 20 is fixed to the second lever 3. Then, the light switch knob 10 is fixed together with the connecting member 5 to the third lever 4 protruding from the tip of the second lever 3.
A known click mechanism for holding the light switch knob 10 and the fog switch knob 30 for each rotation position can be provided between the knobs, but the illustration is omitted here.

FIG. 6 is a diagram showing an operation process of the lock / cancel mechanism described above. FIG. 6 is a cross-sectional view corresponding to FIG. 5B, but shows a part of the light switch knob 10 and the fixed knob 20 together.
Here, for convenience, the light switch knob 10 side of the fixed knob 20 will be described as being upward and the fog switch knob 30 side will be downward as necessary.
FIG. 6A shows a state in which the light switch knob 10 and the fog switch knob 30 are in the “off” and “fog off” positions, respectively.
The cancel lever 12 of the light switch knob 10 penetrates the through long hole 25 of the fixed knob 20 and is in contact with the wall surface 44a of the slider block 40, and presses the low region 43a of the cam surface. The slider block 40 is pushed down against the return spring 48, and the upper surface is substantially flush with the lower surface of the fixed knob 20 or with a slight gap.

Although the cancel lever 12 presses the low area 43a of the cam surface, the upper surface of the slider block 40 is regulated by the lower surface of the fixing knob 20, and the tip (lower end) of the cancel lever 12 and the low area 43a of the cam surface are formed. There may be a slight gap between them. In any case, the slider block 40 is at a high position leaving a predetermined gap between its lower surface and the bottom surface of the slider block storage portion 35. Therefore, here, both are referred to as the high position state of the slider block.
The tip of the lock piece 50 protruding from the upper surface of the slider block 40 has entered the lock hole 27 of the fixed knob 20, whereby the fog switch knob 30 is locked and cannot be rotated.

When the light switch knob 10 is rotated to the “tail” position, the state shown in FIG. In addition, the single line arrow in a figure shows the rotation direction from the last state.
The cancel lever 12 of the light switch knob 10 moves to the middle in the circumferential direction of the through long hole 25 of the fixed knob 20, but the tip of the cancel lever 12 is still in the low region 43a of the cam surface, and the slider block 40 is in the high position state. Has continued.
Therefore, as in the case where the light switch knob 10 is in the “off” position, the fog switch knob 30 is locked and cannot be rotated from the “fog off” position to the “fog light” position.

FIG. 6C shows a state where the light switch knob 10 is rotated to the “headlight” position.
The cancel lever 12 passes through the through long hole 25 of the fixed knob 20, moves to the high region 43c through the inclined region 43b of the cam surface, and comes into contact with or approaches the wall surface 44b. When the pressing position by the cancel lever 12 moves to the high area 43c of the cam surface, the slider block 40 is pushed down to form a low position state in which a gap s is formed between the upper surface of the slider block 40 and the lower surface of the fixed knob 20. Displace to
The lock piece 50 is urged by the spring 54 and protrudes from the upper surface of the slider block 40. However, the lock piece 50 is held by the slider block 40 in a state of being prevented from being detached from the piece holding portion 41 by the protrusion 52 so as not to drop off. The lock piece 50 is displaced downward together with the slider block. As a result, the tip of the lock piece 50 comes out of the lock hole 27 of the fixing knob 20 and the lock is released.

Accordingly, since the fog switch knob 30 is no longer prevented from moving, the fog switch knob 30 can be rotated from the “fog off” position to the “fog light” position.
The amount of downward displacement of the slider block 40 is preferably equal to or longer than the length that the lock piece 50 has entered the lock hole 27, but even if it is shorter than that, an arcuate slope at the tip of the lock piece 50 Therefore, it suffices if the relationship is such that it can be smoothly pushed down at the opening edge of the lock hole 27 that contacts when the fog switch knob 30 is rotated.

Thereafter, when rotating from the “fog off” position to the “fog light” position, first, the lock piece 50 moved downward integrally with the slider block 40 is below the lower surface of the fixed knob 40 where the gap s is formed. Get in. As the rotation of the fog switch knob 30 proceeds, the cancel lever 12 relatively moves to the low region 43a via the inclined region 43b of the cam surface.
As a result, the slider block 40 is displaced upward by the return spring 48. However, since the lock piece 50 held by the slider block 40 has already been disengaged from the lock hole 27, the lock piece 50 compresses the spring 54 and pushes the tip. It moves while sliding on the lower surface of the fixed knob 20.

FIG. 6D shows a state where the light switch knob 10 is in the “headlight” position and the fog switch knob 30 is rotated to the “foglight” position.
As described above, when the light switch knob 10 is first rotated to the “headlight” position and the headlight is turned on, the fog light can be turned on by rotating the fog switch knob 30 to the “foglight” position. .
The rising wall 44 is separated from the cancel lever 12.

FIG. 6E shows a state in which the light switch knob 10 is rotated to the “tail” position from the state in which the headlight and the fog light are lit.
Although the cancel lever 12 comes to a position close to the wall surface 44a of the slider block 40, the fog switch knob 30 is not affected by the rotation of the light switch knob 10, and the position of the lock piece 50 is not changed from (d).

When the light switch knob 10 is further turned to the “off” position from the state of FIG. 6E, the cancel lever 12 abuts against the wall surface 44a and pushes the slider block 40 in the circumferential direction (left side in the figure). Then, the fog switch knob 30 is rotated back to the “fog off” position.
As a result, the state (a) is restored. That is, when the light switch knob 10 is rotated to the “off” position, the fog switch knob 30 is returned to the “fog off” position in conjunction with it, and the “fog light” is automatically turned off.

  Returning only the fog switch knob 30 to the “fog off” position from the state shown in FIG. 6D when the headlight is lit or the state shown in FIG. Since the wall surface 44a of the slider block 40 is only separated from the cancel lever 12, this is possible without any trouble.

In this embodiment, the operation lever 1 corresponds to the lever in the invention, the light switch knob 10 corresponds to the first rotation knob, and the fog switch knob 30 corresponds to the second rotation knob.
The “off” position corresponds to the first switch position of the first rotary knob in the invention, the “headlight” position corresponds to the predetermined switch position of the first rotary knob, and the “fog off” position corresponds to the first switch position. The “fog light” position corresponds to the second switch position of the second rotary knob, with the first switch position of the second rotary knob.
The cancel lever 12 and the cam surface 43 constitute a cam mechanism in the present invention, and the structure in which the wall surface 44a of the slider block 40 is pushed by the cancel lever 12 forms a return mechanism.
The structure in which the opening side of the lock piece holding part 41 in the slit 46 of the lock piece holding part 41 on which the protrusion 52 of the lock piece 50 slides forms the lock piece retaining means in the invention, and the protrusion 45 of the slider block 40 A structure in which the opening side of the slider block storage portion 35 in the groove 36 of the slider block storage portion 35 that slides forms a slider block retaining means.

This embodiment is configured as described above.
The fog switch knob 30 holds the slider block 40 so as to be displaceable in the axial direction, and the cam surface 43 formed on the slider block 40 and the light switch knob 10 pass through the through hole 25 of the fixing knob and the tip of the slider block 40 becomes the cam surface 43. The slider block 40 is displaced in the axial direction in accordance with the relative rotation of the light switch knob 10 and the slider block 40 by the cancel lever 12 that is in contact with the cancel lever 12.
On the slider block 40, the lock piece 50 urged in the protruding direction toward the fixed knob 20 is retained and held.
The fixed knob 20 has a lock hole 27 that can be engaged with the lock piece 50, and when the light switch knob 10 is in a position other than the “headlight” position, the slider block 40 is displaced to the fixed knob 20 side to lock the lock piece 50. Engages with the lock hole 27, and when the light switch knob 10 is in the "headlight" position, the slider block 40 is displaced away from the fixed knob 20 to release the lock piece from engagement with the lock hole. It was supposed to be.

  As a result, when the light switch knob 10 is in a position other than the “headlight” position, the fog switch knob 30 is locked and cannot be turned to the “fog light” position, so only the fog light is lit alone. This eliminates the risk of forgetting to turn it off later.

  The lock piece 50 is urged in the projecting direction from the slider block 40, but is prevented from coming off the slider block 40. Therefore, when the knobs are sequentially assembled to the lever, the lock piece 50 becomes the back side of the fixed knob 20. Even if visual confirmation is impossible, there is no possibility that the lock piece 50 or small parts such as a spring for urging the lock piece will drop off, so that reliable assembly can be performed in a short time and the number of assembly steps can be reduced.

  Further, when the fog switch knob 30 is in the “fog light” position, when the light switch knob 10 is turned to the “off” position, the cancel lever 12 pushes the wall surface 44a of the slider block 40, thereby causing the slider block 40 to move. Since the fog switch knob 30 that holds the lens is rotated to the “fog off” position, the lock is released by setting the light switch knob 10 to the “headlight” position, and the fog switch knob 30 is moved to the “fog light” position. Even if it is forgotten that the fog light has been turned on, the fog light is automatically turned off when the light switch knob 10 is turned to the “off” position.

  In order to prevent the lock piece 50 from coming off, the slider block 40 is provided with a hole-shaped lock piece holding portion 41, an axial slit 46 is provided in the wall of the lock piece holding portion 41, and the lock piece 50 is formed on the side surface. Since the projection 52 is assembled to the lock piece holding portion 41 so that the projection 52 slides on the slit 46, the slit 46 is closed on the opening side of the lock piece holding portion 41. Omission is prohibited.

  In the present embodiment, the cam surface 43 is formed on the bottom of the slider block 40 that is retracted in the axial direction from the upper surface of the slider block 40 that faces the fixed knob 20, and when the light switch knob 10 is rotated to the “off” position, the cancel lever Since the wall surface 44a pressed by 12 is a wall surface connecting the bottom surface where the cam surface 43 is located from the upper surface of the slider block 40 facing the fixed knob 20, a dedicated wall surface for returning the fog switch knob 30 to the "fog off" position. This can be realized with a simple structure.

  Further, the slider block 40 is housed in a slider block housing portion 35 formed on the fog switch knob 30, and an axial groove 36 is provided on the side wall of the slider block housing portion 35. The slider block 40 has a protrusion 45 on the side surface. And the projection 45 is assembled to the slider block storage portion 35 so as to slide in the groove 36, and the opening side of the slider block storage portion 35 in the groove 36 is closed to prevent the slider block 40 from being detached. When assembling the knob to the lever, the operation can be performed without worrying about the slider block 40 falling off.

Next, a second embodiment of the present invention will be described. The second embodiment is also applied to an operation lever of a combination switch installed around a steering column of a vehicle.
FIG. 7 is a longitudinal sectional view showing the configuration of the second embodiment, and FIG. 8 is an exploded perspective view.
In the operation lever 1 ′, the second lever 3 extends to the tip of the outer end of the first lever 2 as in the first embodiment.
The third lever 4 passes through the second lever 3, one end on the switch case side engages with a movable contact member (not shown), and the other end extends to the end of the outer end of the second lever 3. The third lever 4 is rotatable with respect to the second lever 3.

A light switch knob 60 as a first rotating knob is coupled to the distal end portion of the third lever 4 of the operation lever 1 ′ via a connecting member 5 ′, and a fixed knob is coupled to the distal end portion of the second lever 3. 70 is fixed, and a fog switch knob 80 as a second rotating knob is rotatably disposed on the second lever 3 between the distal end portion of the first lever 2 and the fixing knob 70.
Accordingly, the light switch knob 60, the fixing knob 70, and the fog switch knob 80 are arranged adjacent to each other sequentially from the tip of the operation lever 1 ′.

  When the light switch knob 60 is rotated, the third lever 4 is rotated with respect to the second lever 3, and a movable contact member (not shown) on the switch case side is operated to turn on and off the taillight and the headlight. Is switched. In this embodiment, the rotation position of the light switch knob 60 includes three positions of “off” (headlight and taillight off), “tail” (taillight on), and “headlight” (headlight and taillight on). The position is set.

A fixed contact board 6 is provided in the space between the first lever 2 and the second lever 3 in the vicinity of the tip of the first lever 2, and the movable contact 7 facing this is supported by a fog switch knob 80 and can be rotated. ing. These are omitted in FIG.
A wiring (not shown) from the fixed contact board 6 extends in the space between the first lever 2 and the second lever 3 in the direction of the support point on the switch case side. Accordingly, the fog light is switched on and off in accordance with the rotation of the fog switch knob 80. As the rotation position of the fog switch knob 80, two positions of “fog off” (fog light off) and “fog light” (fog light on) are set.

The outer periphery of the tip of the first lever 2 is cut out in a step shape to form a small diameter portion 2a.
In particular, as shown in FIG. 7, the fixed knob 70 has a thick disk shape as a basic shape, and has an overhang portion 71 a on the light switch knob 60 side and a small diameter portion 71 b on the fog switch knob 80 side on the outer periphery.
The light switch knob 60 has a bottomed cylindrical shape, and includes an outer peripheral surface of the light switch knob 60 and an outer peripheral surface of the fixed knob 70 at the opening portion thereof. Is smoothly continuous.

The fog switch knob 80 includes, as a basic shape, an outer cylinder 81, a hub part 83 for fixing to the second lever 3, and a disk wall part 82 connecting the outer cylinder 81 and the hub part 83. Has a pivotable central hole. The hub portion 83 extends to the vicinity of the fixed contact board 6 and supports the movable contact 7.
A fan-shaped recess 86 concentric with the center hole is formed on the end surface of the disk wall 82 on the fixed knob 70 side, and the center side is open to the center hole.
Further, both ends of the outer cylinder 81 are covered with and surrounded by the small diameter portion 71b of the fixed knob 70 and the small diameter portion 2a of the first lever 2, so that the outer peripheral surface of the fog switch knob 80 is fixed to the fixed knob 70 and the first lever on both axial sides. Swells slightly from 2.
The axis of the fixed knob 70 coincides with the axes of the light switch knob 60 and the fog switch knob 80.

A lock / cancel mechanism for the fog switch knob 80 using the slider block 90 is formed between the light switch knob 60, the fixing knob 70, and the fog switch knob 80. The lock / cancel mechanism will be described in detail below.
(A) of FIG. 9 is the figure which looked at the opening end of the light switch knob 60 from the fixed knob 70 side, (b) is a B arrow view in (a).
A release cam 65 corresponding to a cam follower 93 of a slider block 90 described later is formed at the opening end of the light switch knob 60. In particular, as shown in FIG. 9B, the release cam 65 includes a high region 65c formed so as to protrude from the end surface t of the light switch knob 60 in the axial direction toward the fixed knob 70, and an end surface adjacent to the high region 65c. A part of t is a low region 65a, and an inclined region 65b is formed between the high region 65c and the low region 65a.

(C) of FIG. 9 is the figure which looked at the fixed knob 70 from the light switch knob 60 side.
The fixed knob 70 is formed with an arc-shaped slider block housing portion 75 that opens to the end surface on the light switch knob 60 side over a predetermined length range in the circumferential direction.
The slider block storage portion 75 has a flat bottom surface, and a spring support protrusion 77 described later is provided on the bottom surface. Axial grooves 76, 76 closed on the opening surface side of the slider block storage portion are formed on the side walls at both ends in the circumferential direction. FIG. 9C shows the groove 76 in cross section only at one end side.
On the bottom surface of the slider block storage portion 75, a window 79 is provided that can receive around the opening of a piece holding portion 91 of the slider block 90 described later.

FIG. 9D is a view of the fog switch knob 80 as seen from the fixed knob 70 side.
A lock hole 85 is provided at a position facing the lock piece 50 described later when the fog switch knob 80 is in the “fog off” position on the end surface of the disk wall 82 of the fog switch knob 80 on the fixed knob 70 side.
Similarly, the disk wall 82 is formed with a fan-shaped recess 86 concentric with the center hole as described above. A release pin 15 is coupled to the third lever 4 so as to extend in the radial direction and face the sector-shaped recess 86.

When the third lever 4 rotates integrally with the light switch knob 60, the release pin 15 moves between the end walls 87 and 88 at both ends in the circumferential direction that define the sector recess 86 in the sector recess 86.
The second lever 3 is provided with an opening that allows the release pin 15 to move.
Note that the release pin 15 is assembled in the assembly order in which the fog switch knob 80 is assembled on the second lever 3 and then coupled to the third lever 4. A working hole penetrating from the outer peripheral surface of the fog switch knob 80 to the fan-shaped recess 86 can be provided so that the release pin 15 can be inserted toward the four release pin coupling holes.

FIG. 10 is an external perspective view showing the slider block 90 together with the lock piece 50, the return spring 98, and the spring 54.
Here, in the state where the slider block 90 is housed and incorporated in the slider block housing portion 75, the side facing the light switch knob 60 is described as the upper side, and the opposite side is described as the lower side.
The slider block 90 is made of resin having an arc shape as a whole, and includes a piece holding portion 91 for storing and holding the lock piece 50 on one end side in the circumferential direction, and is separated from the piece holding portion 91 in the circumferential direction so as to be held in the spring holding portion 92. And a cam follower 93.

The upper surface of the slider block 90 is flat. The piece holding part 91 and the spring storage part 92 both open downward, but the bottom surface 90a where the piece holding part 91 opens is lower than the bottom surface 90b where the spring storage part 92 opens. That is, the distance between the top surface and the bottom surface is set to be larger on the piece holding portion 91 side than the thickness of the bottom wall 78 of the slider block storage portion 75 in the fixed knob 70.
The bottom surface 90a where the piece holding portion 91 opens and the bottom surface 90b where the spring storage portion 92 opens are parallel and flat with the top surface.
The cam follower 93 is formed on the upper surface in the vicinity of the spring storage portion 92, and the tip has a spherical surface.

  The outer surface of one end in the circumferential direction (piece holding portion 91 side) of the slider block 90 is a flat surface parallel to the axial direction, but has a claw 95 having an inclined surface on the lower side. The outer surface of the other end in the circumferential direction of the slider block 90 (on the side of the spring housing portion 92) is the same, and has a claw 95. After the slider block 90 is pushed into the slider block storage portion 75 of the fixing knob 70 with the bottom face first, the claw 95 slides in the groove 76 of the slider block storage portion 75, and the groove 76 is in the slider block storage portion. Since it is closed on the opening surface side of 75, the slider block 90 is prevented from coming off.

The piece holding part 91 is formed as a hole having a rectangular cross section perpendicular to the axis, like the piece holding part 41 of the previous embodiment, and slits 96 extending in the vertical direction are formed on the inner peripheral side and outer peripheral side walls. Is formed.
The lock piece 50 is the same as that in the previous embodiment, and is slidably held by the piece holding portion 91. A spring 54 is provided between the lock piece 50 and the upper wall of the piece holding portion 91, whereby the lock piece 50 is urged in a direction in which the tip of the lock piece 50 protrudes from the bottom surface of the slider block 90.
After the lock piece 50 is pushed into the piece holding portion 91 and assembled, the projection 52 slides on the slit 96 of the piece holding portion, and the sliding range of the projection 52 is regulated by the lower end of the slit 96, so that the lock piece 50 is removed. It is set to stop.

11A is a view of the fixed knob 70 in a state in which the slider block 90 is housed in the slider block housing portion 75 as viewed from the light switch knob 60 side, and FIG. 11B is a view of C− along the circumferential direction in FIG. It is C section sectional drawing.
A return spring 98 disposed in the spring housing portion 92 of the slider block 90 has one end abutted against the upper wall of the spring housing portion 92 and the other end positioned at the spring support protrusion 77 on the bottom surface of the slider block housing portion 75. The slider block 90 is urged in a direction in which the slider block 90 is separated from the bottom surface of the slider block storage portion 75.
The slider block 90 is urged so that its claws 95 slide in the grooves 76 at both ends in the circumferential direction of the slider block storage portion 75 and protrude from the end face on the light switch knob 60 side of the fixed knob 70. Since the opening portion side of the storage portion 75 is closed as described above, it does not fall off from the fixed knob 70.

The lock piece 50 is urged by the spring 54 and protrudes from the bottom surface 90a of the slider block 90. However, as described above, the protrusion 52 is prevented from coming off at the end of the slit 96 of the piece holding portion 91, and the slider block 90 Will not fall off.
Therefore, with respect to the fixing knob 70, first, the lock piece 50 (and the spring 54) can be assembled to the slider block 90 to form a primary subassembly, and this primary subassembly can be assembled to the fixing knob 70 to form a secondary subassembly.

For attachment to each lever, first, a fog switch knob 80 is rotatably attached on the second lever 3, the release pin 15 is attached to the third lever 4, and then the slider block 90 is incorporated to form a secondary subassembly. The fixing knob 70 is fixed to the second lever 3, and then the light switch knob 60 is fixed together with the connecting member 5 ′ to the third lever 4 protruding from the tip of the second lever 3.
A known click mechanism that holds the light switch knob 60 and the fog switch knob 80 for each rotational position can be provided between the knobs.

12 and 13 are diagrams showing an operation process of the lock / cancel mechanism described above. FIG. 12 is a cross-sectional view corresponding to FIG. 11B, but shows a part of each of the light switch knob 60 and the fog switch knob 80. Here, for the sake of convenience, the light switch knob 60 side of the fixed knob 70 will be described as the upper side and the fog switch knob 80 side as the lower side as necessary.
FIG. 13 shows the relative relationship between the fan-shaped recess 86 of the fog switch knob 80 and the release pin 15.

First, a state where the light switch knob 60 and the fog switch knob 80 are in the “off” and “fog off” positions are shown in FIGS.
As shown in FIG. 12A, the high area 65 c of the release cam 65 of the light switch knob 60 faces and presses the cam follower 93 of the slider block 90, and the slider block 90 is moved inside the slider block storage portion 75. It is pushed down against the return spring 98.
As a result, the bottom surface 90a where the piece holding portion 91 is opened enters the window 79 of the fixing knob 70 and is flush with the end surface of the fog switch knob 80 (that is, the surface facing the fixing knob 70 of the disk wall portion 82) or a slight gap. It is in the low position state which became substantially flush with.

The tip of the lock piece 50 that protrudes from the bottom surface 90a of the slider block 90 enters the lock hole 85 of the fog switch knob 80, whereby the fog switch knob 80 is locked and cannot rotate.
On the other hand, as shown in FIG. 13A, the release pin 15 that rotates integrally with the light switch knob 60 via the third lever 4 follows the end wall 87 of the fan-shaped recess 86 of the fog switch knob 80 in contact. In position.

When the light switch knob 60 is rotated to the “tail” position, the state shown in FIG. 12 and FIG. 13B is obtained. In addition, the single line arrow in a figure shows the rotation direction from the last state.
Although the release cam 65 of the light switch knob 60 moves, the high region 65c still faces the cam follower 93, and the slider block 90 continues to be in the low position.
Therefore, as in the case where the light switch knob 10 is in the “off” position, the fog switch knob 30 is locked and cannot be rotated from the “fog off” position to the “fog light” position.
At this time, the release pin 15 has moved to a substantially intermediate position between the end walls 87 and 88 of the sector-shaped recess 86.

Next, each of FIG. 12 and FIG. 13C shows a state in which the light switch knob 60 is rotated to the “headlight” position.
The release pin 15 that rotates together with the light switch knob 60 moves to the vicinity of the end wall 88 of the fan-shaped recess 86.
On the other hand, in particular, as shown in FIG. 12C, the release cam 65 moves to a position where the low region 65a faces the cam follower 93 through the inclined region 65b.
The slider block 90 biased by the return spring 98 moves upward by the difference in height between the low region 65a and the high region 65c, and a gap is formed between the bottom surface 90a of the slider block 90 and the top surface of the fog switch knob 80. Displacement to the high position where s is formed
The lock piece 50 is urged by the spring 54 and protrudes from the bottom surface 90a of the slider block 90. However, the lock piece 50 is held by the slider block 90 from the piece holding portion 91 by the protrusion 52 so as not to drop off. The lock piece 50 is displaced upward integrally with the slider block 90. As a result, the tip of the lock piece 50 comes out of the lock hole 85 of the fog switch knob 80, and the lock is released.

Accordingly, since the fog switch knob 80 is no longer prevented from moving, the fog switch knob 80 can be rotated from the “fog off” position to the “fog light” position.
The amount of upward displacement of the slider block 90 is preferably equal to or longer than the length that the lock piece 50 has entered the lock hole 85, but even if it is shorter than that, an arcuate slope at the tip of the lock piece 50 Therefore, it is only necessary to smoothly push up at the opening edge of the lock hole 85 that contacts when the fog switch knob 80 rotates.

When the light switch knob 60 is set to the “headlight” position and the fog switch knob 80 is rotated to the “foglight” position, the states shown in FIGS. 12 and 13D are obtained.
During this time, the release pin 15 connected to the light switch knob 60 via the third lever 4 and the connecting member 5 ′ does not move, but the fan-shaped recess 86 moves due to the rotation of the fog switch knob 80, and the fan-shaped recess 86 moves relatively. Only the intermediate position between the end walls 87 and 88 of the recess 86 does not affect the rotation of the fog switch knob 80. As described above, when the light switch knob 60 is first turned to the “headlight” position and the headlight is turned on, the fog light can be turned on by turning the fog switch knob 80 to the “foglight” position. .

Next, when the light switch knob 60 is turned to the “tail” position from the state in which the headlight and the fog light are lit, the state shown in FIG. 12 and FIG. 13 (e) is obtained.
The release cam 65 moves so that the high region 65 c comes to a position facing the cam follower 93. The slider block 90 is pushed down and displaced to the low position state.
At this time, the lock piece 50 protruding downward from the bottom surface 90 a of the slider block 90 is pressed into the piece holding portion 91 while abutting the upper surface of the fog switch knob 80 and compressing the spring 54.
On the other hand, as the light switch knob 60 rotates, the release pin 15 abuts on the end wall 87 or moves to a position near the end wall 87 from the intermediate position in the fan-shaped recess 86.
Therefore, the fog switch knob 80 is not affected by the rotation of the light switch knob 60, and the fog light lighting state continues.

From this state, when the light switch knob 60 is further rotated to the “off” position,
The release pin 15 that is in contact with or in the vicinity of the end wall 87 of the fan-shaped recess 86 pushes the end wall 87 as the light switch knob 60 rotates, and rotates the fog switch knob 80 to move to the “fog off” position. Return to
As a result, the state shown in FIG. 12 and FIG. 13 (a) is restored. That is, when the light switch knob 60 is rotated to the “off” position, the fog switch knob 80 is returned to the “fog off” position in conjunction with it, and the “fog light” is automatically turned off.

  It should be noted that only the fog switch knob 80 is returned to the “fog off” position from the states (d) of FIGS. 12 and 13 where the headlights are lit and the states (e) where the taillights are lit. This is possible without any trouble because the end wall 88 of the fog switch knob 80 is separated from the release pin 15.

In the present embodiment, the operation lever 1 ′ corresponds to the lever in the invention, and in particular, the second lever 3 corresponds to the first lever, and the third lever 4 corresponds to the second lever. The light switch knob 60 corresponds to the first rotation knob, and the fog switch knob 80 corresponds to the second rotation knob. The “off” position corresponds to the first switch position of the first rotary knob in the invention, the “headlight” position corresponds to the predetermined switch position of the first rotary knob, and the “fog off” position corresponds to the first switch position. The “fog light” position corresponds to the second switch position of the second rotary knob, with the first switch position of the second rotary knob.
The release cam 65 corresponds to the cam surface, the release cam 65 and the cam follower 93 form a cam mechanism in the invention, and the structure in which the wall surface 87 of the fan-shaped recess 86 in the fog switch knob 80 is pushed by the release pin 15 forms a return mechanism. ing. The structure in which the opening side of the lock piece holding portion 91 in the slit 96 of the lock piece holding portion 91 on which the protrusion 52 of the lock piece 50 slides forms the lock piece retaining means in the invention, and the protrusion 95 of the slider block 90 A structure in which the opening side of the slider block storage portion 75 in the groove 76 of the slider block storage portion 75 that slides forms a slider block retaining means.

The second embodiment is configured as described above.
A slider block 90 is held on the fixed knob 70 so as to be axially displaceable,
With the release cam 65 formed on the light switch knob 60 and the cam follower 93 provided on the slider block 90, the slider block 90 is displaced in the axial direction in accordance with the relative rotation of the light switch knob 60 and the slider block 90.
In the slider block 90, the lock piece 50 urged in the protruding direction toward the fog switch knob 80 is retained and retained.
The fog switch knob 80 is provided with a lock hole 85 that can be engaged with the lock piece 50 protruding from the slider block 90. When the light switch knob 60 is not in the “headlight” position, the slider block 90 is moved to the fog switch knob 80. When the lock piece 50 engages with the lock hole 85 and the light switch knob 60 is in the “headlight” position, the slider block 90 is displaced to the side away from the fog switch knob 80 to 50 is released from the engagement with the lock hole 85.

  As a result, when the light switch knob 60 is in a position other than the “headlight” position, the fog switch knob 80 is locked and cannot be rotated and cannot be set to the “fog light” position. This eliminates the risk of forgetting to turn it off later.

  The lock piece 50 is urged in the protruding direction from the slider block 90, but is prevented from coming off by the slider block 90. Therefore, when the knobs are sequentially assembled to the lever, the lock piece 50 is moved to the back side of the fixed knob 70. Thus, even if visual confirmation is impossible, there is no possibility that the lock piece 50 or small parts such as a spring for urging the lock piece will drop off, so that reliable assembly can be performed in a short time and the number of assembly steps can be reduced.

  Further, when the fog switch knob 80 is in the “fog light” position, the release pin 15 pushes the wall surface 87 of the fog switch knob 80 when the light switch knob 60 is rotated to the “off” position. Since the knob 80 is turned to the “fog off” position, the lock is released by turning the light switch knob 60 to the “headlight” position, and the fog switch knob 80 is turned to the “fog light” position. When the light switch knob 60 is turned to the “off” position, the fog switch knob 80 is also forcibly turned to the “fog off” position. The fog light is automatically turned off.

  In order to prevent the lock piece 50 from coming off, the slider block 90 includes a hole-shaped lock piece holding portion 91, an axial slit 96 is provided on the wall of the lock piece holding portion 91, and the lock piece 50 is formed on the side surface. Since the protrusion 52 is provided on the lock piece holding portion 91 so that the protrusion 52 slides on the slit 96, the opening of the lock piece holding portion 91 is closed. Omission is prohibited.

In the present embodiment, a fan-shaped recess 86 is formed on the surface of the fog switch knob 80 that faces the fixed knob 70, and the wall 87 in the rotational direction that defines the fan-shaped recess 86 is turned off. The wall surface pressed by the release pin 15 when rotating to the “position” makes it possible to forcibly rotate the fog switch knob 80 to the “fog off” position with a simple structure.
The fan-shaped recess 86 is not limited to the surface of the fog switch knob 80 facing the fixed knob 70, and may be formed on the surface opposite to the fixed knob 70. In this case, the hub portion 83 is partially cut. By notching, the release pin 15 can be extended from the third lever 4 into the sector-shaped recess.

In the second embodiment, the release cam 65 is formed on the light switch knob 60 and the cam follower 93 is provided on the slider block 90. On the contrary, the release cam 65 is formed on the slider block 90 and the cam follower 93 is provided. May be provided in the light switch knob 60.
Further, the slider block 90 is housed in a slider block housing portion 75 formed on the fixed knob 70, and an axial groove 76 is provided on the side wall of the slider block housing portion 75, and the slider block 90 has a protrusion 95 on the side surface. The projection 95 is assembled to the slider block storage portion 75 so as to slide in the groove 76, and the opening side of the slider block storage portion 75 in the groove 76 is closed to prevent the slider block 90 from being removed. When assembling the knob, the slider block 90 can be operated without worrying about dropping off.

In the illustrated embodiment, the lock piece 50 has a rectangular parallelepiped shape and a tip having an arcuate shape in one cross section. However, the present invention is not limited thereto, and the outer shape may be a cylinder and the tip may be spherical.
In each embodiment, the light switch knobs 10 and 60 are coupled to the third lever 4 via the connecting members 5 and 5 ′. However, the light switch knobs 10 and 60 are directly coupled to the third lever 4. You may do it.

  Further, each embodiment is applied to an operation lever for a vehicle, and the light switch knobs 10 and 60 are rotated as a first rotation knob from a “off” position to a second “headlight” position as a predetermined switch position. For the first time, the fog switch knobs 30 and 80 as the second rotary knob are made rotatable. However, the switch position of the first rotary knob that makes the second rotary knob rotatable. Is not limited to the second.

  The present invention can be applied to various other switch levers including an operation lever for a vehicle, and is useful in that the assembling work is easy.

1, 1 'control lever (lever)
2 First lever 3 Second lever (first lever)
4 Third lever (second lever)
5, 5 ′ connecting member 10, 60 Light switch knob (first rotation knob) 12 Cancel lever 15 Release pin 20, 70 Fixing knob 21 Outer cylinder 22 Disc wall portion 23 Hub portion 25 Through long hole 27, 85 Lock hole 30, 80 Fog switch knob (second rotation knob) 35, 75 Slider block storage portion 36, 76 Groove 40, 90 Slider block 41, 91 Piece holding portion 42, 92 Spring storage portion 43 Cam surface 43a Low region 43b Inclination Area 43c High area 44a, 44b Wall surface 45, 95 Claw 46, 96 Slit 48, 98 Return spring 50 Lock piece 54 Spring 52 Projection 65 Release cam (cam surface)
65a Low area 65b Inclined area 65c High area 78 Bottom wall 79 Window 81 Outer cylinder 82 Disk wall part 83 Hub part 86 Fan-shaped recessed part 87, 88 End wall 93 Cam follower

Claims (11)

A first rotation knob, a fixed knob, and a second rotation knob are disposed adjacent to each other along the lever axial direction, and the first rotation knob has a position other than the first switch position and the first switch position. The second rotation knob has a first switch position and a second switch position, and corresponds to each by rotation of the first rotation knob and the second rotation knob. In the lever switch where the switch contact is switched,
One of the fixed knob and the second rotating knob holds a slider block displaceable in the axial direction,
A cam mechanism for displacing the slider block in the axial direction according to the relative rotation of the first rotation knob and the slider block is provided between the first rotation knob and the slider block.
The slider block holds a lock piece biased in a protruding direction toward the other of the fixed knob or the second rotating knob,
The other of the fixed knob or the second rotating knob includes a lock hole that can be engaged with the lock piece protruding from the slider block,
Between the lock piece and the slider block, a lock piece retaining means is provided,
The cam mechanism displaces the slider block to the other side of the fixed knob or the second rotary knob when the first rotary knob is at the first switch position of the first rotary knob. When the first rotary knob is at a predetermined switch position of the first rotary knob, the slider block is displaced away from the other of the fixed knob or the second rotary knob. Yes,
When the first rotation knob is at the first switch position of the first rotation knob, the lock piece is engaged with the lock hole, and the first rotation knob is the first rotation knob. A knob rotation lock structure for a lever switch, wherein the lock piece is released from engagement with the lock hole when the knob is in a predetermined switch position. Holding the slider block on the second rotating knob;
A cancel lever having the cam mechanism extending through a cam surface formed on the slider block and a through hole formed in the fixed knob from the first rotation knob and having a tip abutting on the cam surface And
The lock piece is biased in a protruding direction from the slider block toward the fixed knob,
The lock hole is provided on a surface of the fixed knob facing the second rotation knob,
The cam mechanism displaces the slider block toward the fixed knob when the first rotation knob is at the first switch position of the first rotation knob, and the first rotation knob 2. The knob switch locking structure for a lever switch according to claim 1, wherein the slider block is displaced to a side away from the fixed knob when the first rotation knob is at a predetermined switch position. 3. When the first rotation knob is rotated to the first switch position of the first rotation knob, the second rotation is provided between the first rotation knob and the second rotation knob. A return mechanism is provided for rotating the second rotating knob to the first switch position of the second rotating knob when the moving knob is at the second switch position of the second rotating knob. The lever rotation lock structure of the lever switch according to claim 2, wherein: The cam surface is formed on the bottom of the slider block that is retracted in the axial direction from the surface facing the fixed knob,
The return mechanism is constituted by the cancel lever and a wall surface connecting the bottom portion from a surface facing the fixed knob in the slider block,
When the first turning knob is turned to the first switch position of the first turning knob, the cancel lever pushes the wall surface in the turning direction of the slider block, so that the slider block 4. The knob switch locking structure for a lever switch according to claim 3, wherein the second rotation knob for holding the lever is rotated from the second switch position to the first switch position. Holding the slider block on the fixed knob;
The cam mechanism includes a cam surface formed on one of the first rotation knob or the slider block and a cam follower provided on the other of the first rotation knob or the slider block.
The lock piece is biased in a protruding direction from the slider block toward the second rotation knob,
The lock hole is provided on a surface of the second rotating knob facing the fixed knob,
The cam mechanism displaces the slider block toward the second rotation knob when the first rotation knob is at the first switch position of the first rotation knob, and 2. The lever according to claim 1, wherein when the rotary knob is at a predetermined switch position of the first rotary knob, the slider block is displaced to the side away from the second rotary knob. Switch knob rotation lock structure.   When the first rotation knob is rotated to the first switch position of the first rotation knob, the second rotation is provided between the first rotation knob and the second rotation knob. A return mechanism is provided for rotating the second rotating knob to the first switch position of the second rotating knob when the moving knob is at the second switch position of the second rotating knob. The knob rotation lock structure of the lever switch according to claim 5, wherein The lever includes a first lever that fixes the fixing knob, and a second lever that rotates integrally with the first rotating knob,
The return mechanism includes a recess formed in the second rotating knob and a release pin coupled to the second lever and extending into the recess.
When the first rotation knob is rotated to the first switch position of the first rotation knob, the wall surface in the rotation direction in which the release pin defines a recess in the second rotation knob. 7. The knob switch locking structure of the lever switch according to claim 6, wherein the second rotation knob is rotated from the second switch position to the first switch position by pressing. The slider block includes a hole-shaped lock piece holding portion, and the wall of the lock piece holding portion is provided with an axial slit. The lock piece has a protrusion on a side surface, and the protrusion slides on the slit. As assembled to the lock piece holding part,
The lever turning knob according to any one of claims 1 to 7, wherein the lock piece retaining means is formed by closing an opening side of the lock piece holding portion in the slit. Lock structure. The slider block is housed in a slider block housing portion formed on one of the fixed knob or the second rotating knob,
9. The knob switch lock structure for a lever switch according to claim 1, further comprising means for preventing the slider block from being removed between the slider block and the slider block storage portion. . An axial groove is provided on the side wall of the slider block storage unit,
The slider block has a protrusion on a side surface, and the protrusion is assembled to the slider block storage portion so that the protrusion slides in the groove.
10. The knob switch locking structure for a lever switch according to claim 9, wherein means for preventing the slider block from coming off is formed by closing an opening side of the slider block housing portion in the groove. When the first rotation knob is rotated to the first switch position of the first rotation knob, the second rotation is provided between the first rotation knob and the second rotation knob. A return mechanism is provided for rotating the second rotating knob to the first switch position of the second rotating knob when the moving knob is at the second switch position of the second rotating knob. The knob rotation lock structure of the lever switch according to claim 1, wherein

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