JP2003027808A - Conversion mechanism of sliding mobile force of slide operating body and latch device - Google Patents

Abstract

PROBLEM TO BE SOLVED: To provide sliding mobile force of a slide operating body capable of being smoothly converted into torque without giving any special consideration to clearance between a pivoting body and an axial hole. SOLUTION: The latch device includes a slide operating body 1, the pivoting body 2 having a contact section 2a pushed against a part of the slide operating body 1 in an eccentric position and a housing 3 equipped with the axial hole 3a receiving the pivoting body 2 in a rotatable manner. The pivoting body 2 includes a circumferential faulting face 2d and an elastic piece 2e for the front end to always elastically push against one side of the slide operating body 1. The axial hole 3a includes a circumferential faulting face 3d. The pivoting body 2 is stored into the axial hole 3a in a state to push the circumferential faulting face 2d of the pivoting body 2 against the circumferential faulting face 3d of the axial hole 3a by elasticity of the elastic piece 2a.

Description

Detailed Description of the Invention

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a conversion mechanism for converting a sliding movement force of a slide operation body into a rotational force and a latch device using the conversion mechanism.

[0002]

2. Description of the Related Art Converting the sliding movement force of a slide operating body into a rotating force is performed by sliding the slide operating body at a position eccentric to the center of rotation at one shaft end. A rotary body that has a contact portion that is pressed against the sliding operation body and that is rotated by the pressing to convert the sliding movement force of the slide operation body into a rotational force. It can be secured by rotatably inserting from the hole on the side where it is provided.

That is, by doing this,
The slide movement force of the slide operation body can be output as a rotational force from the shaft end side opposite to the shaft end on the side where the contact portion of the rotary body is provided via the rotating body.

[0004]

However, in such a conversion mechanism, unless special consideration is given to the clearance between the rotating body and the shaft hole, the slide operation of the slide operation body is accompanied. When the rotating body is rotated, it is expected that the rotating body will be shaken in a direction intersecting with the rotation axis or will be displaced in a direction along the rotation axis. In addition, it is expected that such blurring will cause abnormal noise. However,
It is practically difficult to set such clearance strictly, especially when each member constituting such a conversion mechanism is to be provided as a plastic molded product.
Such a strict setting becomes more difficult.

Therefore, according to the present invention, in the mechanism for converting the sliding movement force of the slide operating body into the rotating force by the rotating body rotated by the sliding operation of the slide operating body, the rotating body and the shaft for accommodating the rotating body. The sliding movement force of the slide operation body can be smoothly converted into the rotation force and output by the rotating body without giving special consideration to the clearance between the hole and the hole. It is a main object to provide a latch device using a conversion mechanism.

[0006]

In order to achieve the above object, in the invention according to claim 1, the slide moving force converting mechanism has the following constitutions (1) to (8). I decided. (1) A slide operation body, and (2) a contact portion that is pressed against a part of the slide operation body by a slide operation of the slide operation body at a position eccentric to the rotation center at one shaft end, A rotating body that rotates by the pressing to convert the sliding movement force of the slide operating body into a rotational force, and (3) a shaft that rotatably receives the rotating body from a hole on the side where the slide operating body is provided. (4) The rotating body includes a thick shaft portion, a thin shaft portion, and a circumferential step surface formed by a dimensional difference between the thick shaft portion and the thin shaft portion. An elastic piece formed on the one shaft end is provided so as to constantly elastically press the tip against one surface of the slide operation body. (5) The shaft hole has a large diameter portion and a small diameter portion. , Due to the dimensional difference between the large diameter part and the small diameter part (6) The orbiting step surface of the rotating body is a surface inclined in a direction in which the rotating body is gradually narrowed from the thick shaft portion side toward the thin shaft portion side. As well as
(7) The circumferential step surface of the shaft hole is formed so as to be a surface inclined in a direction in which the shaft hole is gradually narrowed from the large diameter portion side toward the small diameter portion side. The rotary body is housed in the shaft hole in a state in which the circumferential step surface of the rotary body is pressed against the circumferential step surface of the shaft hole by the elasticity of the elastic piece.

According to this structure, the sliding movement force generated by the sliding operation of the sliding operation body is rotated by the rotating body from the shaft end side opposite to the shaft end where the contact portion of the rotating body is provided. Can be converted to and output.

Further, the rotating body is housed in a state in which the circling step surface of the rotator is pressed against the circling step surface of the shaft hole by the elastic piece resiliently revolving, and the rotator is rotated in this state. Since the rotary body is moved, it is difficult for the rotary body to rattle in a direction intersecting with the rotary axis of the rotary body, and is also less likely to rattle in the rotary axis direction of the rotary body.

As a result, according to such a conversion mechanism, even if the clearance between the rotating body and the shaft hole is not particularly taken into consideration, the sliding movement force by the sliding operation of the slide operating body causes abnormal noises, etc. The rotating body can smoothly convert the rotational force into a rotational force and output the rotational force from the side of the shaft end opposite to the shaft end where the abutting portion of the rotating body is provided.

Further, in the invention according to claim 2, in the sliding movement force converting mechanism of the invention according to claim 1, both of the circumferential step surface of the rotating body and the circumferential step surface of the shaft hole are concerned. It is characterized in that the surface is inclined by an angle substantially equal to an imaginary line segment parallel to the rotation axis of the rotating body.

With this structure, the center axis of the virtual cone including the circular step surface can be set as the rotation axis, and the rotation body can be rotated by the sliding operation of the slide operation body without blurring. Can be moved.

Further, in the invention according to claim 3, in the slide moving force converting mechanism according to claim 1 or 2, the tip end of the elastic piece is a slide operation body substantially on the rotation axis of the rotation body. The feature is that it is pressed against one side.

According to this structure, the elastic piece can press the rotating body so as to press the both circumferential step surfaces without tilting the rotating body in the shaft hole, and the rotating body can be pressed without further blurring. It can be rotated by a slide operation of the slide operation body.

In order to achieve the above object, in the invention according to claim 4, the latch device has the following (1).
The structure of (11) to (11) is provided. (1) An insertion portion that is attached to the movable member side and that includes a hooking claw body that is inserted into a hooking hole formed on the fixed member side and is hooked in the hooking hole at a predetermined movement stop position of the moveable member. , (2) A slide knob for retracting and moving the engaging claw body in a direction to release the engagement between the engaging claw body and the engaging hole by a slide operation, and (3) sliding of the slide knob at a position eccentric to the rotation center. A rotating body that has an abutting portion that is pressed against a part of the slide knob by an operation, and that is rotated by the pressing, and (4) Rotate the rotating body from a hole on the side where the slide knob is provided. A latch device comprising a shaft hole that can be received and (5) a biasing unit that constantly biases the engaging claw body to a projecting position, wherein (6) an abutting portion of the rotating body is provided. Side and opposite side Is pressed against a contact portion formed on the side opposite to the protruding side of the engaging claw body by the rotation of the rotating body by the slide operation of the slide knob, and resists the bias of the biasing means. A retracting surface for retracting and moving the engaging claw body is formed, and (7) the rotating body is formed by a thick shaft portion, a thin shaft portion, and a dimensional difference between the thick shaft portion and the thin shaft portion. A round step surface and an elastic piece formed on one axial end of the rotating body provided with the abutting portion so as to constantly elastically press the tip against one surface of the slide knob. (8) The shaft hole includes a large-diameter portion, a small-diameter portion, and an orbital step surface formed by a dimensional difference between the large-diameter portion and the small-diameter portion, and (9) an orbit of the rotating body. The step surface is a direction in which the rotating body is gradually thinned from the thick shaft portion side toward the thin shaft portion side. In addition to being an inclined surface, (10) the circumferential step surface of the shaft hole is a surface inclined so as to gradually narrow the shaft hole from the large diameter portion side toward the small diameter portion side. (11) Moreover, the rotary body is housed in the shaft hole in a state in which the circumferential step surface of the rotary body is pressed against the circumferential step surface of the shaft hole by the elasticity of the elastic piece. There is.

According to this structure, the engaging member is biased by the biasing means by inserting the insertion portion by moving the movable member toward the predetermined movement stop position. After pulling and moving the hooks once again, at the position where the tip of the hooking claw has passed over the hole edge on the insertion destination side of the hooking hole, the hooking claw is moved again to the projecting position by the biasing means. Thus, the movable member can be engaged with the fixed member at the predetermined movement stop position via the latch device.

Further, by sliding the slide knob from the state where the movable member is engaged with the fixed member at the predetermined movement stop position via the latch device, a part of the slide knob is moved. The contact portion of the rotating body can be pressed against and the rotating body can be rotated in the shaft hole.

Thus, the engaging claw body for bringing the contact portion into contact with the pull-in surface by the pull-in surface of the rotating body that is rotated as described above by the slide operation of the slide knob is provided with the biasing means. The movable member can be pulled in and moved against the force, the engaging member is disengaged from the engaging hole, and the movable member can be moved in a direction in which the inserting portion is extracted from the engaging hole again. it can.

Further, the rotating body is housed in the shaft hole with the orbital step surface of the rotating body being pressed against the orbital step surface of the shaft hole by the elastic repulsion of the elastic member. Since the rotary body is moved, it is difficult for the rotary body to rattle in a direction intersecting with the rotary axis of the rotary body, and is also less likely to rattle in the rotary axis direction of the rotary body.

As a result, according to such a latch device, even if the clearance between the rotating body and the shaft hole is not particularly taken into consideration, the sliding movement force caused by the sliding operation of the slide knob causes abnormal noise. It is possible to smoothly convert the rotational force into a rotational force from the shaft end side opposite to the shaft end where the abutting portion of the rotational body is provided, and output the rotational force without generating the rotating claw. The body can be smoothly pulled in and moved against the bias of the biasing means.

In the invention according to claim 5, in the latch device according to claim 4, both the orbital step surface of the rotating body and the orbital step surface of the shaft hole are the rotational axis of the object. It is characterized in that the surface is inclined by an angle substantially equal to a virtual line segment parallel to.

With this structure, the center axis of the virtual cone including the circular step surface can be set as the rotation axis line, and the rotation body can be rotated by the sliding operation of the slide knob without blurring. Can be made.

According to the sixth aspect of the invention, in the latch device according to the fourth or fifth aspect, the tip of the elastic piece is pressed against one surface of the slide knob substantially on the rotation axis of the rotating body. It is characterized by being made to be.

With this structure, the elastic piece can press the rotating body so as to press the both-circumferential step surfaces without tilting the rotating body in the shaft hole, and the rotating body can be pressed without further blurring. It can be rotated by the slide operation of the slide knob.

[0024]

BEST MODE FOR CARRYING OUT THE INVENTION A typical embodiment of the present invention, that is, a slide moving force converting mechanism Hk, and a latch device R1 utilizing this converting mechanism Hk will be described below with reference to FIGS. Will be described.

Here, in FIG. 1, the latch device R1 constructed by using the conversion mechanism Hk is shown in a perspective view, and
FIG. 2 and FIG. 3 show the respective members constituting the latch device R1 as separate perspective views. Also, FIG.
6 to 6 show the latch device R1 viewed from different directions, and FIG. 7 shows the latch device R1 in cross section.

Further, FIG. 8 shows the initial state of the slide operation body 1, here, the latch device R1 before the slide operation of the slide knob 1a, and FIG. 9 shows the slide operation of the slide knob 1a. The respective states are shown. 8A and 9B, the slide knob 1a is shown by a chain double-dashed line in a state where the latch device R1 is seen in a plan view, and the rotary body 2 rotated by the sliding operation of the slide knob 1a is shown. 8 (b) in FIG. 8 and FIG. 9 show the inside of the housing 3 from the upper side 3e side of the housing 3 in a state where the lower space 3h of the housing 3 is a cross section. In addition, the contact portions 6g of the first and second engaging claws 6 and 6 are rotated to prevent the first and second engaging claws 6 and 6 from being biased by the biasing means 7. Retracting surface 10a of the rotating body 2 pressed so as to retract and move.
The raised portion 10 formed on the rotating body 2 is also represented by a chain double-dashed line so that the relationship with

10 and 11 show the usage state of the latch device R1. FIG. 11 shows the usage state from above in FIG.

FIGS. 12 to 18 show the slide knob 1a, FIGS. 19 to 23 show the housing 3, FIGS. 24 to 30 show the rotating body 2, and FIG.
34 to 34 respectively show the first engaging claw body 6 and the second engaging claw body 6.

The latch device R1 shown in FIGS. 1 to 34 is (1) a slide operation body 1 and (2) a slide operation of the slide operation body 1 to rotate and slide movement of the slide operation body 1. A rotating body 2 for converting a force into a rotational force, and (3) a housing 3 having a shaft hole 3a that rotatably receives the rotating body 2 from a hole on the side where the slide operation body 1 is provided. The conversion mechanism Hk for converting the slide movement force of the slide operation body 1 is applied to the latch device R1.

The latch device R1 is attached to the movable member 100 side and the movable member 10
At a predetermined movement stop position of 0, the movable member 100 is engaged at the predetermined movement stop position by engaging with the engagement hole 201 with a part of the engagement hole 201 formed on the fixed member 200 side. It is used to hold.

As the movable member 100, various kinds of lids are typically planned. Further, as the fixing member 200, typically, various articles having the opening provided such that the lid is movable in a direction to open the opening so that the opening is closed by the lid are planned. It

For example, a lid for closing the opening of the glove box provided in the passenger compartment of the automobile can be used so as to be engaged with and held by the glove box body side at the movement stop position for closing the opening.

(Conversion Mechanism Hk) First, the conversion mechanism Hk of the sliding movement force of the slide operating body 1 will be described.

As described above, the converting mechanism Hk comprises the slide operating body 1, the rotating body 2, and the housing 3.

(Housing 3) In the example shown in FIGS. 1 to 34, the housing 3 includes (1) an upper portion 3e, (2) a bottom portion 3f, and (3) an upper portion 3e and a bottom portion 3f. A pair of side parts 3g, 3g between the upper part 3e, (4) a lower space 3h composed of the upper part 3e, the bottom part 3f, and a pair of side parts 3g, 3g, and (5) an outer surface of the upper part 3e. A shaft hole 3a is provided which is open at the inner surface of the upper portion 3e and allows the inside and the outside of the housing 3 to communicate with each other.

The shaft hole 3a is constructed so that the cross-sectional shape of the shaft hole 3a in the direction intersecting with the hole axis line is circular at each position in the hole axis direction.

The rotary body 2 is rotatably housed in the shaft hole 3a of the housing 3 constructed as described above through the hole opening on the outer surface side of the upper portion 3e, and the rotary body 2 is housed in this manner. In this state, the slide operation body 1 is slidably mounted on the outer surface of the upper portion 3e.

(Slide Operation Body 1) The slide operation body 1 is the same as the slide operation body 1 in the examples shown in FIGS.
It is configured as a slide knob 1a.

The slide knob 1a is (1) a knob body 1 having a finger catching portion 1c on one edge thereof in a direction orthogonal to the sliding movement direction of the slide knob 1a.
b, and (2) an assembling portion 1d formed on the back surface side of the knob body 1b, that is, on the side facing the outer surface of the upper portion 3e of the housing 3 and attached to the upper portion 3e of the housing 3.
It has and.

The assembly portion 1d is (1) a pair of guide side portions formed along the sliding movement direction of the slide knob 1a and spaced apart from the other guide side portion 1e. 1e, 1e, and (2) a side of the guide side portion 1e opposite to the side facing the other guide side portion 1e, that is, on the outer surface of the guide side portion 1e, along the extension direction of the guide side portion 1e. A sliding contact plate portion 1g formed with a space between the formed guide rib 1f and (3) the back surface of the knob body 1b so as to extend between the lower end portions of the pair of guide side portions 1e, 1e. (4) The sliding contact plate portion 1g is opened outward at the plate edge side opposite to the hook portion 1c, and the hook portion 1g.
It is provided with a cutout portion 1h formed in the sliding contact plate portion 1g so as to arrange the inner back portion on the c side.

Further, in the example shown in FIGS. 1 to 34, the sliding contact plate portion 1g of the slide knob 1a.
The inner back portion of the cutout portion 1h formed in 1 is configured to press the contact portion 2a of the rotating body 2 described later by the sliding operation of the slide knob 1a.

Further, in this example, the upper portion 3e of the housing 3 projects outward from the edge of the side portion 3g on both sides of the housing 3 where the side portion 3g is not formed. The slide knob 1 is provided on the upper surface side of the portion that is projected in this way.
A rising portion 3 that continues for a long time along the slide movement direction of a.
i is formed. That is, in this example, the rising portions 3i are provided on both sides of the shaft hole 3a with the hole opening therebetween so as to continue for a long time in a direction intersecting with the wall surface of the side portion 3g. A guide groove 3j is formed on the side of the rising portion 3i facing the other rising portion 3i along the length direction of the rising portion 3i. The guide grooves 3j open the groove ends outward at both ends of the rising portion 3i.

In this example, the guide rib 1f of the slide knob 1a is inserted into the guide groove 3j of the rising portion 3i from one groove end of the guide groove 3j, so that the guide rib 3f extends along the guide groove 3j. The slide knob 1a is assembled to the housing 3 so that the slide knob 1a can be slid regularly.

Further, in this example, a pair of rising portions 3i, 3 formed on the upper portion 3e of the housing 3 are used.
Between i and a side wall of the shaft hole 3a, a wall portion 3k having wall surfaces arranged in a direction substantially intersecting the extension direction of the rising portion 3i is formed, and the slide knob 1 is provided.
A fixed portion 1i at the spring end protruding toward the wall portion 3k is formed between the sliding contact plate portion 1a of a and the rear surface of the knob body 1b, and can be slid on the upper portion 3e of the housing 3 as described above. One spring end is fixed to the fixed portion 1i of the slide knob 1a assembled to the
The compression coil spring 4 is interposed between the fixing portion 1i and the wall portion 3k in a state where the other spring end is fixed.

As a result, in this example, the slide operation of the slide knob 1a is performed against the bias of the compression coil spring 4, and the slide operation is performed at the position where the slide operation is completed. When you stop the slide operation,
The slide knob 1a is pushed back to the position before the start of the slide operation by the elastic force of the compression coil spring 4.

Further, in this example, the outer surface of the upper portion 3e of the housing 3 is provided between the pair of rising portions 3i and 3i and the hole of the shaft hole 3a.
A groove 3m is formed along the extending direction of the rising portion 3i, and the sliding contact plate portion 1 of the slide knob 1a is formed.
On the outer surface of g, there is provided a retaining projection 1j which is inserted into the groove 3m when the guide rib 1f is inserted into the guide groove 3j, and the groove 3m is provided at a position approximately in the middle in the longitudinal direction. A stopper that elastically rides over the slip-out preventing projection 1j as the slip-out preventing projection 1j is inserted into the groove 3m, and after this slip-out preventing projection 1j is caught by the compression coil spring 4 in the groove 3m. The protrusion 3n is formed so that the assembled state of the housing 3 and the slide knob 1a is maintained.

(Rotating Body 2) In the example shown in FIGS. 1 to 34, the rotating body 2 is eccentric with respect to the center of rotation of the rotating body 2 at one shaft end of the rotating body 2. To the position where the slide operation body 1 is slid, a part of the slide operation body 1, that is, the slide contact plate portion 1
It has an abutting portion 2a that is pressed to the inner depth of the notch portion 1h of g, and is rotated in the shaft hole 3a by the pressing to convert the sliding movement force of the slide operation body 1 into a rotational force. It is as a composition.

In this example, the contact portion 2a has
It is configured to have a protrusion shape that protrudes from the shaft end surface of the rotating body 2 facing the hole opening of the shaft hole 3a on the outer surface side of the upper portion 3e of the housing 3 in a direction substantially orthogonal to the shaft end surface.

Further, the rotating body 2 has (1) a thick shaft portion 2b from a shaft end side where the abutting portion 2a is provided to a position approximately in the longitudinal direction of the rotating body 2 as a thick shaft portion 2b. ) A thin shaft portion 2c having an outer diameter smaller than that of the thick shaft portion 2b is provided between the end position of the thick shaft portion 2b and the shaft end opposite to the shaft end where the contact portion 2a is provided. (3) Between the thick shaft portion 2b and the thin shaft portion 2c, there is an orbital step surface 2d formed by the dimensional difference between the thick shaft portion 2b and the thin shaft portion 2c. The slide operation body positioned directly above the shaft end surface provided with the contact portion 2a of the rotating body 2 housed in the shaft hole 3a as described above at the shaft end provided with the contact portion 2a. No. 1 surface, in this example, a bullet formed so as to always elastically press the tip against the outer surface of the sliding contact plate portion 1g. It has a single-2e.

In this example, the elastic piece 2e is
A pair of split grooves 2f, 2f formed with a space from the edge of the shaft end surface of the rotary body 2 toward the center of rotation of the rotary body 2 and the other split groove 2f, and this pair of split grooves 2f, 2f. Split groove 2f,
In the state in which both groove ends are in communication with the groove end on the rotation center side of the rotating body 2 in 2f, one of the shaft end faces is formed by the communicating split groove 2g provided between the pair of split grooves 2f, 2f. It is formed by dividing the parts. Further, the rotating body 2 has an internal space 2h facing the inner surface of the elastic piece 2e on the side where the elastic piece 2e is formed, and the elastic deformation of the elastic piece 2e is allowed by the internal space 2h. Has been done. Further, in this example, the elastic piece 2e
A circular protrusion 2i protruding from the shaft end face is formed at the tip of the outer surface of the circular protrusion 2i thus protruded.
Is pushed into the outer surface of the sliding contact plate portion 1g and the elastic piece 2
e is flexed into the internal space 2h, and as a result, the elastic piece 2e is always at its tip, that is, the circular protrusion 2i.
Is pressed against the outer surface of the sliding contact plate portion 1g.

Also, in this example, the shaft hole 3a is
(1) The large diameter portion 3b extends from the hole on the outer surface of the upper portion 3e of the housing 3 to a position approximately in the middle of the axial direction of the shaft hole 3a, and (2) from the end position of the large diameter portion 3b, The area up to the hole on the inner surface of the upper portion 3e of the housing 3 is a small diameter portion 3c having an inner diameter smaller than that of the large diameter portion 3b, and (3) between the large diameter portion 3b and the small diameter portion 3c,
It is provided with a circumferential step surface 3d formed by the dimensional difference between the large diameter portion 3b and the small diameter portion 3c.

The orbital step surface 2d of the rotating body 2 is
The surface gradually increases from the side of the thick shaft portion 2b toward the side of the thin shaft portion 2c so as to narrow the rotating body 2, and the circumferential step surface 3d of the shaft hole 3a has the large diameter. The surface is inclined so as to gradually narrow the shaft hole 3a from the diameter portion 3b side toward the small diameter portion 3c side.

In this example, the revolving member 2 is elastically pressed against the sliding contact plate portion 1g of the slide knob 1a, so that the rotating body 2 is moved to the shaft hole 3 by the elastic force.
It is configured to be housed in a state in which the orbital step surface 2d of the rotating body 2 is pressed against the orbital step surface 3d of the shaft hole 3a.

(Function of conversion mechanism) Since the conversion function described above has the structure described above, (1) slide movement by slide operation of the slide knob 1a, that is, the slide operation body 1. The force can be converted by the rotating body 2 into a rotational force from the shaft end side of the rotating body 2 opposite to the shaft end on which the contact portion 2a is provided, and the rotational force can be output. (2) Further, due to the elastic piece 2e being repulsed, the rotating body 2 is inserted into the shaft hole 3a, and the orbital step surface 2 of the rotating body 2 is formed.
It is housed in a state in which d is pressed against the circumferential step surface 3d of the shaft hole 3a, and is rotated in this state, so that in this rotation, the rotating body 2 intersects with the rotating axis of the rotating body 2. It is difficult to rattle in the direction, and (3) Furthermore, it is also difficult to rattle in the rotation axis direction of the rotating body 2. (4) As a result, according to the conversion mechanism Hk, the slide movement force by the slide operation of the slide operation body 1 can be applied without special consideration to the clearance between the rotating body 2 and the shaft hole 3a. , Without generating abnormal noise,
By the rotating body 2, the contact portion 2a of the rotating body 2
The shaft end side opposite to the shaft end provided with can be smoothly converted into a rotational force and output.

Further, in this example, both the orbital step surface 2d of the rotary body 2 and the orbital step surface 3d of the shaft hole 3a are virtual line segments parallel to the rotational axis of the rotary body 2. The surface is inclined by an angle substantially equal to.

As a result, in this example, the central axis of an imaginary cone including the circular step surfaces 2d and 3d can be set as the rotary axis, and the rotary body 2 can be smoothly moved.
Can be rotated by the slide operation of the slide operation body 1.

Also, in this example, the elastic piece 2e is used.
Of the slide operating body 1 on the substantially rotation axis of the rotating body 2, that is, the circular protrusion 2i,
The sliding contact plate portion 1g is pressed against the sliding contact plate portion 1g.

As a result, in this example, the elastic piece 2e presses the rotating body 2 so as to press the two orbiting step surfaces 2d and 3d without tilting the rotating body 2 in the shaft hole 3a. Therefore, the rotating body 2 can be rotated by the slide operation of the slide operating body 1 without further blurring.

(Latch Device R1) Next, the latch device R1 constructed by including the conversion mechanism Hk described above will be described.

The latch device R1 is (1) attached to the movable member 100 side, and
At a predetermined movement stop position of the above, the insertion portion 5 provided with the engagement claw body 6 that engages with the engagement hole 201 formed on the side of the fixing member 200 and engages with the engagement hole 201, and (2) slides the engagement. A slide knob 1a for retracting and moving the engaging claw 6 in a direction to release the engagement between the claw 6 and the engaging hole 201, and (3) a slide operation of the slide knob 1a at a position eccentric with respect to the rotation center. A rotating body 2 that has an abutting portion 2a that abuts against a part of the knob 1a, and that is rotated by the abutting;
(4) A shaft hole 3a that rotatably receives the rotating body 2 from a hole on the side where the slide knob 1a is provided,
(5) An urging unit 7 that constantly urges the engaging claw body 6 to the projecting position.

Specifically, in the example shown in FIGS. 1 to 34, the engaging claws 6 are provided in the lower space 3h of the housing 3 of the conversion mechanism Hk.
From the urging means 7 so that the urging means 7 always protrudes to the side, and the rotating body 2 is rotated by the slide operation of the slide knob 1a against the urging of the urging means 7. The latch device R1 is configured so that the hooking claw body 6 is retracted and moved.

That is, in this example, the lower space 3h side of the housing 3 functions as the insertion portion 5.

In this example, of the upper part 3e constituting the housing 3, the projecting end of the projecting part provided with the rising part 3i is attached to the outer surface of the movable member 100, respectively. Is provided.

More specifically, in this example, the mounting portion 8 has one end surface located on the same plane as the projecting end surface of the rising portion 3i, and the other end surface located on the lower surface of the projecting portion. That is, the lower space 3h of the housing 3
It is positioned on the same surface as the surface of the projecting portion facing to the side, and is configured to have a columnar shape having a threaded hole 8a in a penetrating state between the both end surfaces.

In this example, the end face of the mounting portion 8 facing the bottom portion 3f side with respect to the mounting hole 101 formed in the movable member 100 is the mounting hole 1
01 to the outer surface of the movable member 100 on the side of the housing 01 in the mounting hole 101.
The movable member 10 by using the screw hole 8a formed in the mounting portion 8 with the bottom portion 3f inserted.
The housing 3 is attached to 0. The portion of the housing 3 mounted in this way that protrudes from the inner surface of the movable member 100 through the mounting hole 101 of the movable member 100 serves as the insertion portion 5.

Also, in this example, the insertion portion 5
In the lower space 3h formed on the side of the bottom 3f of the housing 3 that becomes, the two engaging claw bodies 6, 6, that is,
The first engaging claw body 6 and the second engaging claw body 6 are housed in such a state that the tips thereof are constantly protruded from the projecting opening 9 communicating with the lower space 3h by the urging of the urging means 7. Has been.

In this example, the lower space 3h is
It is composed of the upper portion 3e, the bottom portion 3f, and a pair of side portions 3g, 3g, and communicates with the lower space 3h on the bottom portion 3f side of the housing 3 which is not closed by the pair of side portions 3g, 3g. The protruding opening 9
Are formed.

Then, the first engaging claw body 6 projects its tip from one side of the projecting opening 9 thus formed by the urging of the urging means 7, and the second engaging claw body. 6 is configured so that its tip is projected from the other side of the projecting opening 9 thus formed by the biasing means 7.

The first and second engaging claws 6 and 6 are respectively on the projecting side from the projecting opening 9 by the bias of the biasing means 7 and the side facing the slide knob 1a. As the engaging surface 6a to the engaging hole 201 provided in the fixing member 200 moves toward the tip of the engaging claw body 6 toward the bottom 3f of the housing 3, the thickness of the engaging claw body 6 gradually increases. It is provided with an inclined surface 6b that is inclined in a direction to reduce the size.

Thus, in this example, the movable member 100 is moved so that the insertion portion 5 is inserted into the engaging hole 201, and the fixed member 200 is moved.
The inclination of the inclined surface 6b abutted against the hole edge portion of the engaging hole 201 on the outer surface side 202 of the first and second engaging claw bodies 6 against the bias of the biasing means 7. 6 can be gradually pulled in and moved, and the insertion portion 5
When the slide hook 1a is inserted into the hooking hole 201, the tips of the first and second hooking claw bodies 6 are fixed to the inner surface side 203 of the fixing member 200 without sliding the slide knob 1a.
The insertion part 5 can be inserted from the hole edge of the engaging hole 201 in to the position where it is inserted first.

Further, in this example, the first and second engaging claws 6, 6 are constructed to have substantially the same size and shape.

The first and second engaging claw bodies 6,
6 also has a pair of leg pieces 6c on the side opposite to the projecting side, (1) extending along the moving direction against or biased by the biasing means 7 of the engaging claw bodies 6, 6c,
(2) Between the pair of leg pieces 6c, 6c, a fixed protrusion 6f of a spring end portion protruding in the same direction as the leg piece 6c,
(3) Of the pair of leg pieces 6c, 6c, a pin shape protruding toward the upper side at the tip side of one leg piece 6c, which is located directly below the hole opening of the shaft hole 3a. And a contact portion 6g forming

Further, in this example, one upper surface 6d of the pair of leg pieces 6c, 6c (the surface located on the hole mouth side of the shaft hole 3a) and the pair of leg pieces 6c, 6c. On the other hand, the bottom surface 6e of the leg piece 6c provided with the contact portion 6g (the bottom portion 3 located on the side opposite to the top surface 6d).
so that it is located on the same plane as
The pair of leg pieces 6c, 6c are provided in different steps, and the contact portion 6g of the second engaging claw body 6 is provided below the leg piece 6c on which the contact portion 6g of the first engaging claw body 6 is provided. The leg piece 6c not provided with is provided, and the contact portion 6g of the first engaging pawl body 6 is provided below the leg piece 6c provided with the contact portion 6g of the second engaging pawl body 6. The leg pieces 6c that are not inserted are inserted into the first and second urging means 7 against the urging force of the urging means 7 as the rotating body 2 is rotated by the slide operation of the slide knob 1a. Both of the engaging claws 6, 6 are retracted and moved. (Figs. 8 to 9)

In this example, the biasing means 7
Is the first engaging claw body 6 from one spring end to the inside of the spring.
Of the second engaging claw body 6 from the other spring end to the inside of the spring from the other spring end while the one of the spring ends is pressed against the first engaging claw body 6. 6f
State in which the other spring end is elastically deformed in the compression direction between the first and second engaging claw bodies 6 so that the other spring end is pressed against the second engaging claw body 6. It is configured as a compression coil spring 7a housed in.

Further, in this example, at the shaft end of the rotating body 2 opposite to the side where the contact portion 2a is provided,
The rotation of the rotating body 2 by the sliding operation of the slide knob 1a causes the first and second engaging claw bodies 6, 6 to be rotated.
There is formed a pull-in surface 10a which pushes against the contact portion 6g to resist the bias of the biasing means 7 and pulls and moves the first and second engaging claw bodies 6.

In this example, the pull-in surface 10
a is projected from the shaft end surface of the rotating body 2 opposite to the side where the abutting portion 2a is provided, enters the lower space 3h from the shaft hole 3a, and protrudes toward the inner surface of the bottom portion 3f. (The surface that is formed) is formed in the raised portion 10 that is located above the upper surface of the leg piece 6c provided with the contact portion 6g of the first and second engaging claw bodies 6 and 6.

Specifically, the raised portion 10 is formed on the axial end surface of the rotating body 2 so as to extend from the center of rotation of the rotating body 2 toward both sides in the diametrical direction of the rotating body 2. At the same time, a jaw portion 10b is provided on the edge side of the rotating body 2 around the shaft end surface, and the jaw portion 10b is laterally hooked by the biasing means 7 against the contact portion 6g.

That is, in this example, the one jaw 10b of the raised portion 10 is laterally caught by the biasing means 7 against the contact portion 6g of the first engaging claw body 6. Together with the other jaw 10b of the raised portion 10.
Is configured to be laterally hooked to the contact portion 6g of the second engaging claw body 6 by the urging force of the urging means 7, and one of which sandwiches the center of rotation of the rotating body 2. ,
The first engaging claw body 6 is provided on one side surface of the raised portion 10 in the protruding direction (the surface in the rotation axis direction of the rotating body 2).
Contacting part 6g of the second engaging claw body 6 on the other side of the protruding part 10 in the protruding direction, which is the other side sandwiching the center of rotation of the rotating body 2. 6 g
Are configured to contact. (Fig. 8 (b))

Then, in the state in which the urging means 7 receives the urging force in the protruding direction by the rotating body 2 for hooking the jaws 10b of the protrusions 10 on the contact portions 6g of the engaging claws 6 in this way, respectively. Each of these engaging claws 6 is held at the protruding position.

Specifically, in this example, a part of the hole on the outer surface side of the upper portion 3e of the housing 3 in the shaft hole 3a is part of the side portion on the hole side of the rotating body 2. The formed stopper projection 11 is expanded outward so as to be housed, and the urging means 10 urges the urging means 7 by hooking the raised portion 10 on the contact portion 6g to rotate (see FIGS. 8 and 9). The rotating body 2 that receives a rotational force in a counterclockwise direction) has a stepped surface 13 formed between the hole opening 12 of the shaft hole 3a and the inner peripheral surface of the shaft hole 3a thus expanded. The stopper projections 11 are abutted against each other to hold the engaging claw bodies 6 at the protruding positions.

Since the latch device R1 shown in FIGS. 1 to 34 has the structure described above, (1) the interval between the facing hole edges is set to the first engaging position at the projecting position. Engagement hole 201 that is smaller than the dimension between the tip of the pawl 6 and the tip of the second engaging pawl 6 at the protruding position.
On the other hand, by inserting the insertion portion 5 by moving the movable member 100 toward the predetermined movement stop position, both the first and second engaging claw bodies 6 and 6 are After retracting and moving once against the urging force of the urging means, at the position where the tips of the first and second engaging claws 6 and 6 have passed over the hole edge on the insertion destination side of the engaging hole 201. , Both the first and second engaging claws 6 and 6 are moved to the projecting position again by the biasing means, and the movable member 100 is moved to the predetermined stop position via the latch device R1. It can be engaged with the fixing member 200. (2) Further, by sliding the slide knob 1a from the state in which the movable member 100 is engaged with the fixed member 200 at the predetermined movement stop position via the latch device R1, the slide is performed. Part of the knob 1a, that is, the cutout portion 1 of the sliding contact plate portion 1g.
The abutting portion 2a of the rotating body 2 is pressed against the inner depth of h to rotate the rotating body 2 in the shaft hole 3a (in the clockwise direction in FIGS. 8 and 9). it can.

In this example, the rotating body 2
Is caused by the engaging claws 6 urged by the urging means 7 toward the protruding position.
From the position where 1 is abutted against the stepped surface 13, the stopper protrusion 11 is separated from the stepped surface 13 by the sliding operation of the slide knob 1a, that is, the contact portion 6g of each engaging claw body 6 is Retracting surface 1
It is configured so that it is rotated only in the direction in which it is pressed toward the inner side of the lower space 3h of the housing 3 by 0a.

Specifically, the rotary body 2 is a virtual straight line along the sliding movement direction of the slide knob 1a.
The step surface 13 and the stopper projection 11 are abutted on one side of an imaginary line segment passing through the center of rotation, and the contact portion 2a and the slide are slid on the other side of the imaginary line segment. A part of the knob 1a, that is, the inner depth of the cutout portion 1h of the sliding contact plate portion 1g comes into contact with the knob 1a. (Figure 8 (a) Figure)

Further, in this example, the rotation of the rotating body 2 in this direction allows the rotation of the rotating body 2 in such a clockwise direction, so that the jaw portion of the raised portion 10 is rotated. 1
0b is provided inside each of the pair of side portions of the housing 3 to accommodate the side where the 0b is provided.

(3) Accordingly, in this example, the contact portion 6g is attached to the pull-in surface 10a by the pull-in surface 10a of the rotating body 2 which is rotated as described above by the sliding operation of the slide knob 1a. The two engaging claws 6 and 6 that contact each other can be retracted and moved against the urging of the urging means 7 (FIG. 9), whereby the first and second engaging claws 6 can be moved. , 6 and the engagement hole 201 are released, and the movable member 100 can be moved in a direction in which the insertion portion 5 is pulled out from the engagement hole 201 again.

(4) When the slide operation of the slide knob 1a is stopped after the insertion portion 5 is pulled out from the engaging hole 201 in this way, the urging means 7 urges
Both the first and second engaging claw bodies 6 and 6 are moved to the projecting position again, and the pulling surface 10a is brought into contact with the contact portion 6g of both engaging claw bodies 6 and 6 thus moved. The rotating body 2 is returned to the rotating position (the position shown in FIG. 8) before the start of the slide operation of the slide knob 1a.

(5) Along with that, the slide knob 1a
Is moved to the position before the start of the slide operation by the urging of the urging means 4 for urging the slide knob 1a,
A return to the initial state is achieved.

[0088]

According to the present invention, in the mechanism for converting the sliding movement force of the slide operation body into the rotation force by the rotating body rotated by the slide operation of the slide operation body, and the latch device using the mechanism, The sliding movement force of the slide operation body is smoothly converted into a rotational force by the rotating body and outputted without any special consideration for the clearance between the rotating body and the shaft hole for accommodating the rotating body. You can

[Brief description of drawings]

FIG. 1 is a perspective view of a latch device R1 using a conversion mechanism Hk.

FIG. 2 is an exploded perspective view of the same.

FIG. 3 is the same exploded perspective view from a direction different from FIG.

FIG. 4 is a side view of the same.

FIG. 5 is a plan view of the same.

FIG. 6 is a bottom view of the same.

FIG. 7 is a vertical sectional view of the same.

FIG. 8 is a plan configuration diagram ((a) diagram) showing an initial state of the latch device R1 and a cross-sectional configuration diagram ((b) diagram) on the bottom 3f side of the housing 3.

FIG. 9 is a plan configuration diagram ((a) diagram) showing a latch release state of the latch device R1 and a lateral cross-sectional configuration diagram ((b) diagram) on the bottom 3f side of the housing 3.

FIG. 10 is a side view showing a usage state of the latch device R1.

FIG. 11 is a side view showing a usage state of the latch device R1 from a direction different from that of FIG.

FIG. 12 is a plan view of a slide knob 1a.

FIG. 13 is a bottom view of the same.

FIG. 14 is a side view of the same.

FIG. 15 is the same slide knob 1a as seen from a direction different from FIG.
Side view

FIG. 16 is a side view of the slide knob 1a viewed from a different direction from FIGS. 14 and 15.

17 is a cross-sectional view taken along the line AA in FIG.

18 is a sectional view taken along line BB in FIG.

FIG. 19 is a side view of the housing 3.

FIG. 20 is a plan view of the same.

21 is a cross-sectional view taken along the line CC in FIG.

22 is a sectional view taken along line DD in FIG.

23 is a sectional view taken along line EE in FIG.

FIG. 24 is a side view of the rotating body 2.

FIG. 25 is a side view of the rotating body 2 viewed from a direction different from that of FIG. 24.

FIG. 26 is a plan view of the same.

FIG. 27 is a bottom view of the same.

28 is a sectional view taken along line FF in FIG.

FIG. 29 is a partially cutaway side view of the rotating body 2 seen from a direction different from FIGS. 24 and 25.

30 is a cross-sectional view taken along the line GG in FIG. 25.

FIG. 31 is a side view of the first and second engaging claw bodies 6;

32 is a side view seen from the direction of arrows H-H in FIG. 31 ((a) view) and a side view seen from the direction of arrows I-I in FIG. 31 ((b) view).

FIG. 33 is a plan view of the first and second engaging claw bodies 6, 6.

FIG. 34 is a bottom view of the same.

[Explanation of symbols]

1 Slide operation body 2 rotating body 2a contact part 2b thick shaft 2c Thin shaft 2d circular step surface 2e Elastic piece 3 housing 3a shaft hole 3b Large diameter part 3c small diameter part 3d circular step surface

   ─────────────────────────────────────────────────── ─── Continued front page    (72) Inventor Yasushi Kamiya             16 580, Horikawa-cho, Saiwai-ku, Kawasaki-shi, Kanagawa             Within Ryo Automotive Engineering Co., Ltd. (72) Inventor Junya Hirano             16 580, Horikawa-cho, Saiwai-ku, Kawasaki-shi, Kanagawa             Within Ryo Automotive Engineering Co., Ltd. (72) Inventor Hisashi Honma             1 184 Maioka-cho, Totsuka-ku, Yokohama-shi, Kanagawa             Nifco Co., Ltd. F-term (reference) 2E250 AA21 HH01 JJ00 KK01 LL11                       PP03 PP04 QQ03                 3D022 CA08 CD14

Claims (6)

[Claims] 1. A slide operating body, and an abutting portion that is pressed against a part of the slide operating body by a sliding operation of the slide operating body at a position eccentric with respect to a rotation center at one shaft end, and A rotating body that rotates by pressing and converts the sliding movement force of the slide operating body into a rotational force, and a shaft hole that rotatably receives the rotating body from a hole on the side where the slide operating body is provided are provided. The rotating body includes a thick shaft portion, a thin shaft portion, an orbital step surface formed by a dimensional difference between the thick shaft portion and the thin shaft portion, and one surface of the slide operation body. An elastic piece formed on one of the shaft ends is provided so as to constantly elastically press the tip, and the shaft hole has a large diameter part, a small diameter part, and a large diameter part and a small diameter part. Perimeter formed by dimensional difference A step surface, and the orbital step surface of the rotating body is a surface inclined in a direction in which the rotating body is gradually narrowed from the thick shaft portion side toward the thin shaft portion side. The circumferential step surface of the shaft hole is formed so as to be inclined in a direction in which the shaft hole is gradually narrowed from the side of the large diameter portion toward the side of the small diameter portion. The conversion mechanism of the slide movement force of the slide operation body, which is housed in a state in which the orbital step surface of the rotating body is pressed against the orbital step surface of the shaft hole by the elasticity of the elastic piece. . 2. The orbital step surface of the rotary body and the orbital step surface of the shaft hole are both inclined by an angle substantially equal to an imaginary line segment parallel to the rotational axis of the rotary body. The conversion mechanism of the slide movement force of the slide operation body according to claim 1, wherein 3. The slide operating body according to claim 1, wherein the tip of the elastic piece is pressed against one surface of the slide operating body substantially on the rotation axis of the rotating body. Slide movement force conversion mechanism. 4. A plug provided with a hooking member which is attached to the movable member side, and which, at a predetermined movement stop position of the movable member, is fitted into the engaging hole formed on the fixed member side and engages with the engaging hole. Section, a slide knob for retracting and moving the engaging claw body in a direction to release the engagement between the engaging claw body and the engaging hole by a slide operation, and a slide knob for sliding the slide knob at a position eccentric to the rotation center. A rotating body that has a contact portion that is pressed against a part of the knob and that is rotated by the pressing; and a shaft hole that rotatably receives the rotating body from a hole on the side where the slide knob is provided, And a biasing means for constantly biasing the engaging claw body to the projecting position, the slide device being provided on the side opposite to the side where the contact portion of the rotating body is provided. By the rotation of the rotating body by the sliding operation of, the pressing body is pressed against the contact portion formed on the side opposite to the protruding side of the engaging claw body, and the engaging claw body is pushed against the bias of the biasing means. A retraction surface for retracting and moving is formed, and the rotating body includes a thick shaft portion, a thin shaft portion, an orbital step surface formed by a dimensional difference between the thick shaft portion and the thin shaft portion, and the slide body. An elastic piece formed at one shaft end of the rotating body provided with the abutting portion so as to constantly elastically press the tip on one surface of the knob, and the shaft hole has a large diameter. And a small-diameter portion, and an orbital step surface formed by a dimensional difference between the large-diameter portion and the small-diameter portion. The orbital step surface of the rotating body is a thin shaft portion from the thick shaft portion side. The surface is gradually inclined toward the side of the rotating body so as to narrow the rotating body. In addition, the circumferential step surface of the shaft hole is formed so as to be a surface inclined in a direction in which the shaft hole is gradually narrowed from the large diameter portion side toward the small diameter portion side. The latch device is housed in a state in which the orbital step surface of the rotating body is pressed against the orbital step surface of the shaft hole by the elasticity of the elastic piece in the shaft hole. 5. The orbital step surface of the rotary body and the orbital step surface of the shaft hole are both inclined by an angle substantially equal to an imaginary line segment parallel to the rotational axis of the rotary body. The latch device according to claim 4, wherein the latch device is provided. 6. The latch device according to claim 4, wherein the tip of the elastic piece is pressed against one surface of the slide knob substantially on the rotation axis of the rotating body.