WO2016092637A1 - Slider for slide fastener, and method for manufacturing same - Google Patents

Abstract

The upper wing plate (10) of a slider (400) is provided with first to fourth protrusions (110, 120, 130, 140). The first to fourth protrusions (110, 120, 130, 140) are provided with first to fourth engagement recesses (111, 121, 131, 141) in which the first to fourth engagement protrusions (211, 221, 231, 241) of a plate spring (200) are arranged. The first to fourth engagement recesses (111, 121, 131, 141) are provided in order to define a vertical range in which the first to fourth engagement protrusions (211, 221, 231, 241) can move as a pull tab (300) is pivotally operated. In an alternative example, the third and fourth protrusions (130, 140) are staked, and the third and fourth engagement recesses (131, 141) and the third and fourth engagement protrusions (231, 241) are omitted.

Description

Slider for slide fastener and manufacturing method thereof

The present disclosure relates to a slider for a slide fastener and a manufacturing method thereof.

It is known that the slider is switched between a movable state and a non-movable state by controlling the degree of protrusion of the claw into the element passage of the slider body in accordance with the posture of the handle on the slider body. A slider to which such switching control is given is generally one in which the slider is set in a non-movable state when the handle falls on the slider body, and is also called a slider with an automatic stop function for short.

As for this type of slider, as can be understood from the comparison between FIG. 1 and FIG. 2 of Patent Document 1, when holding the pivot shaft portion of the handle by the plastic deformation of the column provided on the upper blade of the slider body There is.

On the other hand, as disclosed in Patent Document 2, a type that does not involve plastic deformation of a column provided on the upper blade of the slider body is also known.

JP 2013-6083 A Utility model registration No. 3173803

The inventor of the present application has found the significance of stable support of the pivot shaft portion of the handle and simplification of the component configuration while ensuring the degree of freedom of the attachment timing of the handle and the leaf spring to the slider body.

The slider according to an aspect of the present invention includes a slider body (100) in which an upper wing plate (10) and a lower wing plate (20) are connected via a connecting column (30), and the slider body (100). A plate spring (200) to be mounted; and a handle (300) having a pivot shaft portion (310) sandwiched between the plate spring (200) and the slider body (100). ) On the upper wing plate (10) by the locking claw (205) of the leaf spring (200) in response to the pivoting operation of the handle (300) to invert the handle (300). A slider (400) for a fastener slider that is displaced upward in a hole (15),
The upper wing plate (10) includes first to fourth protrusions (110, 120, 130, 140), and the first to fourth protrusions (110, 120, 130, 140) include the first protrusions. The leaf spring (200) is disposed between the portion (110) and the second protrusion (120) and between the third protrusion (130) and the fourth protrusion (140). One end of the pivot shaft part (310) is disposed between the protrusion part (110) and the third protrusion part (130), and the second protrusion part (120) and the fourth protrusion part (140). Between the other end of the pivot shaft (310) is provided between,
The first and second protrusions (110, 120) are respectively provided with first and second engaging protrusions (211, 221) of the leaf spring (200). Joint recesses (111, 121) are provided, and each of the first and second engagement recesses (111, 121) corresponds to each of the first and second engagement protrusions (211 when the handle (300) is pivoted. 221) to determine the upper and lower movable range,
Furthermore, the third and fourth engaging protrusions (231, 241) of the leaf spring (200) are disposed on the third protrusion (130) and the fourth protrusion (140), respectively. Third and fourth engaging recesses (131, 141) are provided, and each of the third and fourth engaging recesses (131, 141) corresponds to each of the third and fourth when the handle (300) is pivoted. It is provided to define the movable range above and below the engaging projections (231, 241).

In some embodiments, when the claw hole (15) is provided between the first protrusion (110) and the second protrusion (120), the first to fourth engagement recesses (111). , 121, 131, 141) have upper stop surfaces (111c, 121c, 131c, 141c) for restricting the upward displacement of the first to fourth engaging convex portions (211, 221, 231, 241), The first engaging recess (111) and the second engaging recess (121) are longer than the third engaging recess (131) and the fourth engaging recess (141). , 131c, 141c) toward the upper blade (10).

In some embodiments, when the handle (300) falls on the upper blade (10), the upper end of the first engagement recess (111) and the first engagement protrusion (211) A first clearance exists between the upper end of the second engagement recess (121) and the second engagement protrusion (221), and the third engagement recess ( 131) and a third clearance between the upper end of the fourth engagement recess (141) and the third engagement protrusion (241). Has a fourth clearance,
When the handle (300) falls on the upper blade (10), the first and second clearances are larger than the third and fourth clearances.

In some embodiments, the first engagement recess (111) is recessed inward in the left-right direction of the first protrusion (110), and the second engagement recess (121) is the second The protrusion (120) is recessed inward in the left-right direction, and the third engagement recess (131) is recessed inward in the left-right direction of the third protrusion (130), and the fourth engagement recess (141). ) Is recessed inward in the left-right direction of the fourth protrusion (140).

In some embodiments, the first engagement recess (111) is released rearward, the second engagement recess (121) is released rearward, and the third engagement recess (131) is forward. The fourth engaging recess (141) is released forward.

In some embodiments, the first engagement recess (111) is released rearward, the second engagement recess (121) is released rearward, and the third engagement recess (131) is rearward. The fourth engaging recess (141) is released rearward.

In some embodiments, the distance between the side surface (111a) orthogonal to the left-right direction of the first engagement recess (111) and the side surface (121a) orthogonal to the left-right direction of the second engagement recess (121) ( W21) is greater than the distance (W22) between the side surface (131a) orthogonal to the left-right direction of the third engagement recess (131) and the side surface (141a) orthogonal to the left-right direction of the fourth engagement recess (141). large.

In some embodiments, the third protrusion (130) and the fourth protrusion (140) include a ridge (135, 145) extending toward the front end of the upper blade (10), The height of the raised portions (135, 145) gradually decreases toward the front end portion of the upper blade (10).

In some embodiments, the leaf spring (200) receives a force from the pivoting shaft portion (310) that rotates and the cup-shaped passive portion (201) in which the locking claw (205) is displaced up and down. ) And a spring base (202) shaped in a U shape to hold the passive part (201) in its original position against the force received by the passive part (201) from the pivot shaft part (310) Consists of
The slider body (100) is provided with a spring accommodating portion (35) extending from the upper blade (10) to the lower blade (20),
The locking claw (205) is provided at one end of the plate spring (200), and the locked piece (204) stored in the spring storage portion (35) is provided at the other end of the plate spring (200). And
The passive part (201) includes a first plate part in which the first engaging convex part (211) and the second engaging convex part (221) are provided to protrude oppositely in the left-right direction, and the third part A second plate connecting the first and third plate portions with a third plate portion provided with an engagement convex portion (231) and the fourth engagement convex portion (241) protruding oppositely in the left-right direction. Part
The leaf spring (200) is bent to have the first to third plate portions,
The spring base (202) is connected to the third plate portion on the side opposite to the second plate portion side.

The slider according to another aspect of the present invention includes a slider body (100) in which an upper wing plate (10) and a lower wing plate (20) are connected via a connecting column (30), and the slider body (100). A plate spring (200) to be mounted; and a handle (300) having a pivot shaft portion (310) sandwiched between the plate spring (200) and the slider body (100). ) On the upper wing plate (10) by the locking claw (205) of the leaf spring (200) in response to the pivoting operation of the handle (300) to invert the handle (300). A slider (400) for a fastener slider that is displaced upward in a hole (15),
The upper wing plate (10) includes first to fourth protrusions (110, 120, 130, 140), and the first to fourth protrusions (110, 120, 130, 140) include the first protrusions. The leaf spring (200) is disposed between the portion (110) and the second protrusion (120) and between the third protrusion (130) and the fourth protrusion (140). One end of the pivot shaft part (310) is disposed between the protrusion part (110) and the third protrusion part (130), and the second protrusion part (120) and the fourth protrusion part (140). Between the other end of the pivot shaft (310) is provided between,
The first and second protrusions (110, 120) are respectively provided with first and second engaging protrusions (211, 221) of the leaf spring (200). Joint recesses (111, 121) are provided, and each of the first and second engagement recesses (111, 121) corresponds to each of the first and second engagement protrusions (211 when the handle (300) is pivoted. 221) to determine the upper and lower movable range,
Further, the third protrusion (130) and the fourth protrusion (140) are provided to be bent toward the first protrusion (110) and the second protrusion (120), respectively. The protrusion (130) and the fourth protrusion (140) have upper end portions (133, 143) toward the first protrusion (110) and the second protrusion (120), respectively.
An interval between the upper end (133) of the third protrusion (130) and the first protrusion (110) is sandwiched between the first protrusion (110) and the third protrusion (130). Greater than the width of the pivot shaft (310);
An interval between the upper end portion (143) of the fourth protrusion portion (140) and the second protrusion portion (120) is sandwiched between the second protrusion portion (120) and the fourth protrusion portion (140). It is larger than the width of the pivot shaft (310).

In some embodiments, when the claw hole (15) is provided between the first protrusion (110) and the second protrusion (120), the upper surface of the upper blade (10) A groove portion (16) is provided, and the bottom surface of the groove portion (16) coincides with a lower stop surface that restricts downward displacement of the first and second engaging convex portions (211 and 221).

In some embodiments, the leaf spring (200) receives a force from the pivoting shaft portion (310) that rotates and the cup-shaped passive portion (201) in which the locking claw (205) is displaced up and down. ) And a spring base (202) shaped in a U shape to hold the passive part (201) in its original position against the force received by the passive part (201) from the pivot shaft part (310) Consists of consecutive.

The slider manufacturing method according to still another aspect of the present invention includes a slider body (100) in which an upper wing plate (10) and a lower wing plate (20) are connected via a connecting column (30), and the slider body ( 100) and a leaf spring (200) attached to the slider 100, and an automatic stop including a handle (300) having a pivot shaft portion (310) sandwiched between the leaf spring (200) and the slider body (100). Set the slider with function (400)
The upper wing plate (10) includes first to fourth protrusions (110, 120, 130, 140), and the first to fourth protrusions (110, 120, 130, 140) include the first protrusions. The leaf spring (200) is disposed between the portion (110) and the second protrusion (120) and between the third protrusion (130) and the fourth protrusion (140). One end of the pivot shaft part (310) is disposed between the protrusion part (110) and the third protrusion part (130), and the second protrusion part (120) and the fourth protrusion part (140). Between the other end of the pivot shaft (310) is provided between,
The first and second protrusions (110, 120) are respectively provided with first and second engaging protrusions (211, 221) of the leaf spring (200). Joint recesses (111, 121) are provided, and each of the first and second engagement recesses (111, 121) corresponds to each of the first and second engagement protrusions (211 when the handle (300) is pivoted. 221), the slider (400) manufacturing method provided to define the upper and lower movable ranges,
A first injection molding of at least the upper wing plate (10), the lower wing plate (20), the connecting column (30), and the first to fourth protrusions (110, 120, 130, 140) is integrally performed. Process,
The third protrusion (130) is bent by the punch tool toward the first protrusion (110), and the fourth protrusion (150) is bent by the punch tool toward the second protrusion (120). By bending the second projection portion (110, 120, 130, 140), only the third projection portion (130) and the fourth projection portion (140) of the first to fourth projection portions (110, 120, 130, 140) are selectively deformed. Process,
After the second step, the first protrusions between the first protrusions (110) and the third protrusions (130) and between the second protrusions (120) and the fourth protrusions (140). (110) and the third protrusion (130) and the upper opening between the second protrusion (120) and the fourth protrusion (140) through the upper opening between the third protrusion (130) and the handle (300). A third step of inserting and arranging the pivot shaft (310);
After the third step, the leaf spring (200) is mounted on the slider body (100) without deforming the slider body (100), and the leaf spring (200) is moved from the slider body (100). A fourth step of preventing the pulling of the handle (300);

According to one aspect of the present invention, it is possible to stably support the pivot shaft portion of the handle and simplify the component configuration while ensuring the degree of freedom of the timing of attaching the handle and the leaf spring to the slider body.

It is a disassembled perspective view of the slider which concerns on 1st Embodiment of this invention, and shows the state before mounting | wearing a handle with a leaf | plate spring with respect to a slider main body. It is a perspective view of the slider which concerns on 1st Embodiment of this invention, and shows the state with which the handle was mounted | worn with the leaf | plate spring with respect to the slider main body. It is a partial top view of the slider which concerns on 1st Embodiment of this invention, and is in the state which the handle fell on the upper wing board. FIG. 4 is a partial cross-sectional schematic diagram of the slider according to the first embodiment of the present invention, schematically showing a cross section taken along IV-IV in FIG. 3. FIG. 5 is a partial cross-sectional schematic diagram of the slider according to the first embodiment of the present invention, schematically showing a cross section taken along line VV of FIG. 3. It is a partial rear view of the slider which concerns on 1st Embodiment of this invention, and the 1st and 2nd engagement convex part of a leaf | plate spring contacts the bottom face of a groove part, and the latching claw of a leaf | plate spring protrudes in the element channel | path. . It is a partial front view of the slider which concerns on 1st Embodiment of this invention, and the 3rd and 4th engagement convex part of a leaf | plate spring is contacting the frame part provided in the upper blade. FIG. 4 is a partial schematic cross-sectional view of the slider corresponding to the cross-section along IV-IV in FIG. 3 according to the first embodiment of the present invention, and is a schematic cross-sectional view in a state where the handle is inverted on the slider body. FIG. 5 is a partial schematic cross-sectional view of the slider corresponding to the cross-section taken along the line VV of FIG. 3 according to the first embodiment of the present invention, and is a schematic cross-sectional view in a state where the handle is inverted on the slider body. It is a disassembled perspective view of the slider which concerns on 2nd Embodiment of this invention, and shows the state before mounting | wearing a handle with a leaf | plate spring with respect to a slider main body. It is a perspective view of the slider which concerns on 2nd Embodiment of this invention, and shows the state with which the handle was mounted | worn with the leaf | plate spring with respect to the slider main body. It is a manufacturing-process figure of the slider which concerns on 2nd Embodiment of this invention, The protrusion part before crimping with a punch tool is shown with a dotted line, and the protrusion part after crimping with a punch tool is typically shown with a continuous line. . FIG. 6 is a partial rear view of a slider in a state in which a handle has fallen on an upper blade according to a second embodiment of the present invention, where the first and second engaging convex portions of the leaf spring are in contact with the bottom surface of the groove portion, The locking claw protrudes into the element passage. FIG. 14 is a partial cross-sectional schematic diagram of a slider according to a second embodiment of the present invention, schematically showing a cross section taken along XIV-XIV in FIG. 13. FIG. 14 is a partial cross-sectional schematic diagram of a slider according to a second embodiment of the present invention, schematically showing a cross section taken along XV-XV in FIG. 13. It is a cross-sectional schematic diagram of a slider according to a second embodiment of the present invention, and shows a state where a handle is pulled obliquely upward and the pivot shaft portion of the handle is restrained by a third protrusion. It is a perspective view of the slider which concerns on 3rd Embodiment of this invention, and shows the state by which the handle was mounted | worn with the leaf | plate spring with respect to the slider main body. It is a top view of the slider which concerns on 3rd Embodiment of this invention, and shows the state in which the handle fell on the upper wing board of the slider main body. It is a perspective view of the slider main body of the slider which concerns on 3rd Embodiment of this invention.

Hereinafter, embodiments of the present invention will be described with reference to the drawings. The embodiments are not individually independent, and need not be overexplained. Those skilled in the art can appropriately combine the embodiments, and can also grasp the synergistic effect of the combination. In principle, duplicate descriptions between the embodiments are omitted. The reference drawings are mainly intended to explain the invention and are simplified as appropriate.

In the present disclosure, the vertical direction is the direction in which the connecting pillar that connects the upper blade and the lower blade extends. The vertical direction is also a direction orthogonal to both the upper blade plate and the lower blade plate. The left-right direction is not necessarily limited to this, but is the direction in which the pivot shaft portion of the handle extends. The front-rear direction is a direction orthogonal to the up-down direction and the left-right direction. Each direction can also be redefined in a different expression based on the following disclosure.

<First Embodiment>
The first embodiment will be described with reference to FIGS. FIG. 1 is an exploded perspective view of the slider, showing a state before the handle is attached to the slider body by a leaf spring. FIG. 2 is a perspective view of the slider and shows a state in which a handle is attached to the slider body by a leaf spring. FIG. 3 is a partial top view of the slider, with the handle lying on the upper wing plate. FIG. 4 is a schematic partial cross-sectional view of the slider, schematically showing a cross-section taken along IV-IV in FIG. FIG. 5 is a partial cross-sectional schematic view of the slider, schematically showing a cross section taken along line VV of FIG. FIG. 6 is a partial rear view of the slider, in which the first and second engaging convex portions of the leaf spring are in contact with the bottom surface of the groove portion, and the locking claws of the leaf spring protrude into the element passage. FIG. 7 is a partial front view of the slider, in which the third and fourth engaging convex portions of the leaf spring are in contact with the frame portion provided on the upper blade. FIG. 8 is a partial schematic cross-sectional view of the slider corresponding to the cross-section along IV-IV in FIG. 3, but is a schematic cross-sectional view in a state where the handle is inverted on the slider body. FIG. 9 is a partial schematic cross-sectional view of the slider corresponding to the cross-section along VV in FIG. 3, and is a schematic cross-sectional view in a state where the handle is inverted on the slider body.

As shown in FIGS. 1 to 9, the slider 400 includes a slider body 100, a leaf spring 200, and a handle 300. The slider 400 is a slider for a slide fastener. The pair of left and right fastener stringers are closed by the forward movement of the slider 400, and the pair of right and left fastener stringers are opened by the backward movement of the slider 400. The slider 400 is a slider with a so-called automatic stop function described at the beginning. Therefore, when the handle 300 falls on the slider body 100, the slider 400 is controlled to stop, in other words, non-movable. On the other hand, when the handle 300 is inverted on the slider body 100, the slider 400 is controlled to be movable. Switching between the movable state and the non-movable state of the slider 400 is based on a change in the relative position in the vertical direction of the locking claw 205 of the leaf spring 200 with respect to a fastener chain or a fastener element (not shown).

The slider 400 is manufactured by attaching the handle 300 to the slider body 100 using the leaf spring 200. As will be apparent from the following description, in the present embodiment, the attachment timing of the handle 300 to the slider body 100 is not accompanied by the partial plastic deformation of the slider body 100, for example, the caulking of the column described at the beginning. A degree of freedom is secured. For example, the slider body 100 can be manufactured in advance to ensure stock. Even when the handle 300 is manufactured according to the specifications of individual customers, the slider body 100 is manufactured in advance, so that early delivery of the slider is promoted.

The manufacturing methods of the slider body 100, the leaf spring 200, and the handle 300 are arbitrary. For example, the slider body 100 is manufactured by die casting and subsequent surface treatment. The pull handle 300 is manufactured through press working, bending work, cutting work and surface treatment of a metal material. In another form, the handle 300 is manufactured by die casting and subsequent surface treatment. The material of the slider body 100 is a metal, for example, zinc or a zinc alloy in one example, and a resin in another example. The material of the leaf spring 200 is a metal in one example. The material of the handle 300 is a metal in one example, and a resin in another example.

The slider main body 100 has an upper wing plate 10, a lower wing plate 20, and a connecting column 30. The upper wing plate 10 and the lower wing plate 20 are vertically opposed to each other, and the front end portions of the upper wing plate 10 and the lower wing plate 20 are connected through the connecting pillars 30, thereby constructing a Y-shaped element passage. The A flange portion 11 is provided on the left and right side edges of the upper wing plate 10 so as to protrude downward, and a flange portion 21 is provided on the left and right side edges of the lower wing plate 20 so as to protrude upward. The movement of the fastener element is stabilized.

The connecting column 30 extends straight between the front end of the upper blade 10 and the front end of the lower blade 20 in the vertical direction. A pair of front openings are provided on both the left and right sides of the connecting column 30, and the unengaged fastener elements pass through. One rear port is provided at the rear end portion of the slider main body 100 opposite to the front end portion of the slider main body 100 provided with the connecting column 30, and the meshed fastener element passes therethrough.

A support portion for supporting the pivot shaft portion 310 of the handle 300 is provided on the upper surface of the upper blade plate 10, and first to fourth protrusion portions 110, 120, 130, and 140 are provided at the ends. The first to fourth protrusions 110, 120, 130, and 140 according to the illustrated example are all columnar protrusions, and can also be called column parts. However, in other embodiments, the first to fourth protrusions 110, 120, 130, and 140 can take other shapes than the columnar protrusions. The term “projection” is intended to be interpreted in a broad sense. That is, the “projection” includes a column, a ridge, and a protrusion, and also includes any combination of these.

The first to fourth protrusions 110, 120, 130, and 140 are provided in such a manner as to sandwich the pivot shaft portion 310 and the leaf spring 200. Specifically, the leaf spring 200 is disposed between the first protrusion 110 and the second protrusion 120 and between the third protrusion 130 and the fourth protrusion 140. The left end of the pivot shaft 310 is sandwiched between the first projection 110 and the third projection 130, and the right end of the pivot shaft 310 is sandwiched between the second projection 120 and the fourth projection 140. It is.

An arcuate surface that slowly falls in the opposite direction in the front-rear direction when viewed from an intermediate position between the first protrusion 110 and the third protrusion 130 at the upper end of the first protrusion 110 and the upper end of the third protrusion 130. Is provided. An arcuate surface that slowly falls in the opposite direction in the front-rear direction when viewed from an intermediate position between the second protrusion 120 and the fourth protrusion 140 at the upper end of the second protrusion 120 and the upper end of the fourth protrusion 140. Is provided. It is desirable to make the upper end of each protrusion non-sharp with such an arcuate surface.

The arrangement of the four protrusions 110 to 140 is similar to a conventional configuration that requires caulking of the protrusions. However, in the present embodiment, four points between the protrusions 110 to 140 and the leaf spring 200 are obtained while obtaining the benefit of stable support of the pivot shaft portion by the four protrusions resulting from the conventional configuration. This eliminates the need for caulking of the protrusions 110-140. It is worthy of special mention that the approach similar to the prior art is adopted at first glance, but it is not necessary to crimp the protrusion for mounting the leaf spring 200 on the slider body 100. Since the configuration disclosed in Patent Document 2 omits two of the four pillars, a decrease in the stable support of the pivot shaft portion of the handle is expected. It is considered that the configuration disclosed in Patent Document 2 is not so strong against the twist of the handle.

A first engagement recess 111 is provided on the inner side of the first protrusion 110 in the left-right direction, and the first engagement protrusion 211 of the leaf spring 200 is disposed in the first engagement recess 111. The first engagement recess 111 is provided to define a movable range of the first engagement protrusion 211 when the handle 300 is pivoted. The first engagement recess 111 is a recess in which the inner surface in the left-right direction of the first protrusion 110 is stepped down to the outer side in the left-right direction, and is released rearward, and the first engagement protrusion 211 of the leaf spring 200 is released. Suitable to accept. The upper end of the first engaging recess 111 is at a lower position than the upper end of the first protrusion 110, and the upper side surface of the first engaging recess 111 prevents the first engaging protrusion 211 from moving upward. Functions as a stop surface.

A second engagement recess 121 is provided inside the second protrusion 120 in the left-right direction, and the second engagement protrusion 221 of the leaf spring 200 is disposed in the second engagement recess 121. The second engagement recess 121 is provided to define a movable range of the second engagement protrusion 221 when the pulling handle 300 is pivoted. The second engagement recess 121 is a recess in which the inner surface in the left-right direction of the second protrusion 120 is stepped down to the outer side in the left-right direction, and is released rearward, and the second engagement protrusion 221 of the leaf spring 200 is released. Suitable to accept. The upper end of the second engagement recess 121 is at a lower position than the upper end of the second protrusion 120, and the upper side surface of the second engagement recess 121 prevents the second engagement protrusion 221 from moving upward. Functions as a stop surface.

A third engagement recess 131 is provided on the inner side of the third protrusion 130 in the left-right direction, and the third engagement protrusion 231 of the leaf spring 200 is disposed in the third engagement recess 131. The third engagement recess 131 is provided so as to define a movable range of the third engagement protrusion 231 when the handle 300 is pivoted. The third engagement recess 131 is a recess in which the inner surface in the left-right direction of the third protrusion 130 is stepped down to the outer side in the left-right direction, and is released forward, and the third engagement protrusion 231 of the leaf spring 200 is released. Suitable to accept. The upper end of the third engagement recess 131 is at a lower position than the upper end of the third protrusion 130, and the upper side surface of the third engagement recess 131 prevents the third engagement protrusion 231 from moving upward. Functions as a stop surface.

A fourth engagement recess 141 is provided on the inner side of the fourth protrusion 140 in the left-right direction, and the fourth engagement protrusion 241 of the leaf spring 200 is disposed in the fourth engagement recess 141. The fourth engagement recess 141 is provided to define a movable range of the fourth engagement protrusion 241 when the pulling handle 300 is pivoted. The fourth engagement recess 141 is a recess in which the inner surface in the left-right direction of the fourth protrusion 140 is stepped down to the outer side in the left-right direction, and is released forward, and the fourth engagement protrusion 241 of the leaf spring 200 is released. Suitable to accept. The upper end of the fourth engagement recess 141 is lower than the upper end of the fourth protrusion 140, and the upper side surface of the fourth engagement recess 141 prevents the fourth engagement protrusion 241 from moving upward. Functions as a stop surface.

The heights of the first to fourth protrusions 110 to 140 when the upper surface of the upper blade 10 is used as a reference are equal. The first protrusion 110 and the second protrusion 120 are provided mirror-symmetrically with respect to a plane extending in the front-rear direction at the left-right center of the slider body 100. Similarly, the third projecting portion 130 and the fourth projecting portion 140 are provided mirror-symmetrically with respect to the surfaces.

The first engagement recess 111 and the third engagement recess 131 are recessed inward in the left-right direction of the first protrusion 110 and the third protrusion 130. The first engaging recess 111 is recessed on the rear side of the first protrusion 110. The third engagement recess 131 is recessed on the front side of the third protrusion 130. Thus, the first engagement recess 111 and the third engagement recess 131 are released in the same direction in the left-right direction and in the opposite direction in the front-rear direction.

The second engagement recess 121 and the fourth engagement recess 141 are recessed on the inner side in the left-right direction of the second protrusion 120 and the fourth protrusion 140. The second engagement recess 121 is recessed on the rear side of the second protrusion 120. The fourth engagement recess 141 is recessed on the front side of the fourth protrusion 140. Thus, the second engagement recess 121 and the fourth engagement recess 141 are released in the same direction in the left-right direction and in the opposite direction in the front-rear direction.

As shown in FIG. 6, the first engaging recess 111 includes a first side surface 111 a and a second side surface 111 b that are orthogonal to each other and extend vertically upward from the bottom surface of the groove 16 that is recessed in the upper surface of the upper blade 10. And an upper side surface 111c perpendicular to them at the upper ends of the first side surface 111a and the second side surface 111b. The first side surface 111a is a flat surface extending in the front-rear direction. The second side surface 111b is a flat surface extending in the left-right direction. The upper side surface 111c is a flat surface orthogonal to the vertical direction. The first engaging recess 111 is provided with a space defined by the bottom surface of the groove portion 16, the first side surface 111a, the second side surface 111b, and the upper side surface 111c. This space is released on the second projecting portion 120 side, and further on the rear side.

The second engagement recess 121 has a first side surface 121a and a second side surface 121b that are perpendicular to each other and extend vertically upward from the bottom surface of the groove 16 that is recessed in the upper surface of the upper blade 10. It has the upper side 121c orthogonal to them at the upper end of the side 121a and the second side 121b. The first side surface 121a is a flat surface extending in the front-rear direction. The second side surface 121b is a flat surface extending in the left-right direction. The upper side surface 121c is a flat surface perpendicular to the vertical direction. The second engagement recess 121 is provided with a space defined by the bottom surface of the groove portion 16, the first side surface 121a, the second side surface 121b, and the upper side surface 121c. This space is released on the first protrusion 110 side, and further on the rear side.

As shown in FIG. 7, the third engagement recess 131 has an orthogonal relationship that extends vertically upward from the lower side surface 131 d that is higher than the bottom surface of the groove 16 that is recessed in the upper surface of the upper blade 10. It has a first side surface 131a and a second side surface 131b, and further has an upper side surface 131c orthogonal to them at the upper ends of the first side surface 131a and the second side surface 131b. The first side surface 131a is a flat surface extending in the front-rear direction. The second side surface 131b is a flat surface extending in the left-right direction. The upper side surface 131c and the lower side surface 131d are flat surfaces perpendicular to the vertical direction. The third engagement recess 131 is provided with a space defined by the lower side surface 131d, the first side surface 131a, the second side surface 131b, and the upper side surface 131c. This space is released on the fourth projecting portion 140 side, and further on the rear side.

The fourth engaging recess 141 has a first side surface 141a and a second side surface that are perpendicular to each other and extend vertically upward from a lower side surface 141d that is higher than the bottom surface of the groove 16 that is recessed in the upper surface of the upper blade 10. 141b, and further has an upper side surface 141c perpendicular to them at the upper ends of the first side surface 141a and the second side surface 141b. The first side surface 141a is a flat surface extending in the front-rear direction. The second side surface 141b is a flat surface extending in the left-right direction. The upper side surface 141c and the lower side surface 141d are flat surfaces perpendicular to the vertical direction. The fourth engaging recess 141 is provided with a space defined by the lower side surface 141d, the first side surface 141a, the second side surface 141b, and the upper side surface 141c. This space is released on the third projecting portion 130 side, and further on the rear side.

The upper side surfaces 111c, 121c, 131c, and 141c described above are upper stop surfaces.

The groove 16 is formed in the upper surface of the upper blade 10 so that the lower ends of the first engagement recess 111 and the second engagement recess 121 can be lowered. The groove 16 extends straight from the rear end of the upper blade 10 toward the front end of the upper blade 10 in the front-rear direction. The groove 16 extends to the second side surface 111b of the first engagement recess 111 and the second side surface 121b of the second engagement recess 121 with a certain width W16a, and thereafter extends with the reduced width W16b. The groove 16 is provided in such a manner that it communicates with a later-described spring accommodating portion 35, thereby preventing the leaf spring 200 from protruding from the upper blade 10.

The lower end of the first engaging recess 111 coincides with the bottom surface of the groove 16, and the bottom surface of the groove 16 serves as a lower stop surface for preventing the first engaging protrusion 211 from moving downward when the handle 300 is pivoted. Function. The lower end of the second engagement recess 121 coincides with the bottom surface of the groove portion 16, and the bottom surface of the groove portion 16 serves as a lower stop surface for preventing the second engagement protrusion 221 from moving downward during the pivoting operation of the pull handle 300. Function.

A claw hole 15 is provided in the left and right center of the first protrusion 110 and the second protrusion 120 of the upper blade 10, and the locking claw 205 of the leaf spring 200 is displaced up and down through the claw hole 15. Since the lower ends of the first engaging recess 111 and the second engaging recess 121 are lowered by the groove 16, the first engaging recess 111 even if the height of the first protrusion 110 and the second protrusion 120 is lowered. And sufficient vertical length of the 2nd engagement crevice 121 can be secured. The vertical length indicates the dimension from the upper end to the lower end of each engagement recess. The claw hole 15 is formed in a taper shape that extends from the bottom surface of the groove portion 16 to the lower surface of the upper wing plate 10 and whose left and right widths are narrowed downward.

The lower end and the lower side surface 131d of the third engagement recess 131 coincide with the upper surface of the frame portion 17 provided on the upper blade 10 in a U shape so as to surround the spring accommodating portion 35. The upper surface functions as a lower stop surface for preventing downward movement of the third engagement recess 131 when the pulling handle 300 is pivoted. The lower end and the lower side surface 141 d of the fourth engagement recess 141 coincide with the upper surface of the frame portion 17 provided on the upper blade 10, and the upper surface of the frame portion 17 is the fourth engagement during the pivoting operation of the pull handle 300. It functions as a lower stop surface for preventing the concave portion 141 from moving downward. Note that the frame portion 17 may be configured by only a portion extending in parallel in the front-rear direction, excluding a portion extending in the left-right direction.

The stop surface can be suitably set by providing the frame portion 17 on the upper surface of the upper blade 10. A form in which the upper surface of the upper wing plate 10 is utilized as a stop surface for the third engagement convex portion 231 and the fourth engagement convex portion 241 without providing the frame portion 17 is also assumed. In any case, the lower end of the third engaging recess 131 and the lower end of the fourth engaging recess 141 are at a height equal to or higher than the bottom surface of the groove 16, for example, at a position equal to or higher than the upper surface of the upper blade 10. . The frame portion 17 protrudes at a certain height on the upper wing plate 10, and its top view shape is U-shaped. The form which fluctuates the protruding height of the frame part 17 is also considered.

As can be understood from the above description, in the present embodiment, the vertical lengths of the first engagement concave portion 111 and the second engagement concave portion 121 are the upper and lower lengths of the third engagement concave portion 131 and the fourth engagement concave portion 141, respectively. Longer than long. In other words, the first engagement recess 111 and the second engagement recess 121 are longer than the third engagement recess 131 and the fourth engagement recess 141 and extend from each upper stop surface toward the upper blade 10 side. . The first engaging recesses are respectively provided for the long movable range of the first engaging convex portion 211 and the second engaging convex portion 221 and the short movable range of the third engaging convex portion 231 and the fourth engaging convex portion 241. The vertical lengths of 111 and the second engagement recess 121 and the vertical lengths of the third engagement recess 131 and the fourth engagement recess 141 are adapted, whereby the force received from the leaf spring 200 is adjusted to the first and second engagements. It can be dispersed in a set of recesses 111 and 121 and a set of third and fourth engagement recesses 131 and 141.

As can be understood from the comparison between FIG. 6 and FIG. 7, the clearance L5 between the second engagement convex portion 221 and the upper end of the second engagement concave portion 121 is the fourth engagement convex portion 241 and the fourth engagement concave portion 141. Is larger than the clearance L6 between the upper ends of the two. For example, the clearance L5 / clearance L6> 2 is satisfied. The same relationship is established for the clearance between the first engagement convex portion 211 and the upper end of the first engagement concave portion 111 and the clearance between the third engagement convex portion 231 and the upper end of the third engagement concave portion 131. To do.

When the pull handle 300 falls on the upper blade 10, there is a first clearance between the upper end of the first engagement recess 111 and the first engagement protrusion 211, and the upper end of the second engagement recess 121 and the first A second clearance exists between the two engaging convex portions 221, a third clearance exists between the upper end of the third engaging concave portion 131 and the third engaging convex portion 231, and a fourth engaging concave portion 141. A fourth clearance exists between the upper end of the first engagement protrusion 241 and the fourth engagement convex portion 241. When the pull handle 300 falls on the upper wing plate 10, the first and second clearances are larger than the third and fourth clearances.

5, the first engaging convex portion 211 and the second engaging convex portion 221 come into contact with the lower ends of the first engaging concave portion 111 and the second engaging concave portion 121, respectively. Further, the third engaging convex portion 231 and the fourth engaging convex portion 241 are in contact with the lower ends of the third engaging concave portion 131 and the fourth engaging concave portion 141, respectively, and the force received from the leaf spring 200 is the first and first. It is distributed between a set of two engaging recesses 111, 121 and a set of third and fourth engaging recesses 131, 141.

9, the first engagement convex portion 211 and the second engagement convex portion 221 come into contact with the upper ends of the first engagement concave portion 111 and the second engagement concave portion 121, respectively. The third engagement convex portion 231 and the fourth engagement convex portion 241 are in contact with the upper ends of the third engagement concave portion 131 and the fourth engagement concave portion 141, respectively, and the force received from the leaf spring 200 is the first and first. It is distributed between a set of two engaging recesses 111, 121 and a set of third and fourth engaging recesses 131, 141.

The first engagement convex portion 211 contacts the upper end of the first engagement concave portion 111 only when the pull handle 300 is pulled excessively upward, and the first engagement convex portion when the pull handle 300 is not excessively pulled upward. A mode in which 211 does not contact the upper end of the first engaging recess 111 is also assumed. The same applies to the relationship between the other second to fourth engaging convex portions and the other second to fourth engaging concave portions.

As described above, the slider main body 100 is provided with the spring accommodating portion 35 that extends from the upper blade plate 10 to the lower blade plate 20 with the connecting column 30 being hollow. The upper portion of the spring accommodating portion 35 is provided in a tapered shape in which the opening width in the front-rear direction gradually decreases downward, and the lower portion is provided in a reverse taper shape in which the opening width in the front-rear direction gradually increases downward. The spring accommodating portion 35 is connected to the bottom surface of the groove portion 16 and has a downwardly inclined surface 35m that descends toward the front, and the insertion of the leaf spring 200 is guided. The spring accommodating portion 35 is provided with a locking portion 35n for locking a locked piece 204 of a plate spring 200 described later. The locking part 35n has a step where the locked piece 204 after getting over the locking part 35n is locked, and thereby the upward movement of the locked piece 204 is prevented. Note that the spring accommodating portion 35 may be open at the front. In this case, the connecting column is formed in a semi-cylindrical shape with the front opened.

The pull handle 300 is a flat plate member having a pivot shaft portion 310 and has a proximal end 301 and a free end 302. The pivot shaft portion 310 is provided at the proximal end 301 of the handle 300. The free end 302 of the pull handle 300 is provided with a grip portion that is gripped by a human hand. Openings 320 and 330 are provided on the proximal end 301 side and the free end 302 side of the pull handle 300, respectively. The pivot shaft part 310 is a part of a U-shaped bar part surrounding the opening part 320. In the assembled state shown in FIG. 2, the leaf spring 200 is passed through the opening 320 of the handle 300.

The pivot shaft portion 310 of the pull handle 300 has a cam portion 315 having a flat shape, that is, an egg-shaped cross section, at the left and right central portions thereof. In other words, the cam portion 315 of the pivot shaft portion 310 has a longitudinal width and a short width perpendicular to the longitudinal width. When the handle 300 is inverted on the upper wing plate 10, the longitudinal width of the cam portion 315 intersects or intersects the upper wing plate 10, the locking claw 205 is disposed at the non-locking position, and the slider 400 is freely movable. Can move back and forth. When the pull handle 300 falls on the upper wing plate 10, the short width of the cam portion 315 intersects or intersects with the upper wing plate 10, the locking claw 205 is arranged at the locking position, and the slider 400 is free. Back and forth movement is prevented. Both end portions of the pivot shaft portion 310 are non-flat, end-circular in cross section, do not function as a cam portion, and the space between the first protrusion portion 110 and the third protrusion portion 130 and the second protrusion portion. It only rotates in the space between 120 and the fourth protrusion 140.

The leaf spring 200 is a leaf spring manufactured by pressing and bending a metal plate. The leaf spring 200 includes a cup-shaped passive portion 201 and a U-shaped spring base portion 202 that are continuous. The passive portion 201 is a portion including a locking claw 205 that receives a force from the pivoting pivot portion 310 and moves up and down. The spring base portion 202 is a portion for securing the spring property of the leaf spring 200 and operates to keep the passive portion 201 in the original position against the force received by the passive portion 201 from the pivot shaft portion 310.

The above-described locking claw 205 is provided at one end of the leaf spring 200, and a locked piece 204 protruding in the left-right direction is provided at the other end of the leaf spring 200. Between the locking claw 205 and the locked piece 204, a plate body 206 bent at four positions extends. The plate body 206 includes a first plate portion provided with a first engagement convex portion 211 and a second engagement convex portion 221 that protrude in the left-right direction. The plate body 206 includes a third plate portion in which a third engagement convex portion 231 and a fourth engagement convex portion 241 are provided so as to protrude oppositely in the left-right direction. The plate body 206 includes a second plate portion that connects the first plate portion and the third plate portion. The second plate portion is provided with a covering portion 203 provided so as to protrude in the left-right direction. The covering portion 203 is a portion that covers the pivot shaft portion 310 from above, and bites of paper and bags between the first to fourth projecting portions 110, 120, 13, and 140 and the pivot shaft portion 310. It is provided to avoid intrusion. The plate body 206 includes a fourth plate portion that extends forward by being connected to the lower end of the third plate portion, and a fifth plate portion that extends downward from the front end of the fourth plate portion. An arcuate portion is provided at a connecting portion between the fourth plate portion and the fifth plate portion. The first to third plate portions constitute a passive portion 201, and the fourth and fifth plate portions constitute a spring base portion 202. Continuous concave grooves are provided on the upper surface of the fourth plate portion and the front surface of the fifth plate portion, and appropriate flexibility is ensured.

In the state where the pivot shaft portion 310 is disposed between the space between the first protrusion portion 110 and the third protrusion portion 130 and between the second protrusion portion 120 and the fourth protrusion portion 140, the leaf spring 200 is passive. The portion 201 covers the cam portion 315 of the pivot shaft portion 310 and pushes the spring base portion 202 of the leaf spring 200 toward the upper blade plate 10. Then, the distance between the fourth plate portion and the fifth plate portion of the spring base portion 202 is widened, the locked piece 204 descends the inclined surface 35m, gets over the locking portion 35n in the spring accommodating portion 35, and is locked by the locking portion 35n. Locked.

In the state where the spring base 202 is snap-attached to the slider body 100, the spring base 202 is in a state where the distance between the fourth plate portion and the fifth plate portion is widened. Therefore, when the passive portion 201 of the leaf spring 200 is pushed upward by the longitudinal width of the pivot shaft portion 310 due to the inversion of the pull handle 300, the force for returning to the original shape of the spring base portion 202 is transmitted to the passive portion 201, 201 also operates to return to the original position. In other words, the pivot shaft portion 310 of the pull handle 300 is always pushed downward by the passive portion 201 of the leaf spring 200.

As described above, when the pull handle 300 falls on the upper blade 10, the first engaging convex portion 211 and the second engaging convex portion 221 are respectively formed on the first engaging concave portion 111 and the second engaging concave portion 121. The lower displacement is prevented by the lower end, and the third engagement convex portion 231 and the fourth engagement convex portion 241 are prevented from being displaced downward by the lower ends of the third engagement concave portion 131 and the fourth engagement concave portion 141, respectively. . The elastic return force to the original shape of the leaf spring 200 can be dispersed, and a larger elastic return force can be applied to the leaf spring 200. It is also permissible to shorten the vertical width of the first to fourth engaging convex portions 211, 221, 231, 241. The vertical widths of the first to fourth engaging convex portions 211, 221 and 231, 241 are widths along a direction orthogonal to the protruding direction and the thickness direction.

When the handle 300 falls on the upper wing plate 10, the covering portion 203 is disposed below the upper ends of the first protrusion 110 and the third protrusion 130 between the first protrusion 110 and the third protrusion 130. The second protrusion 120 and the fourth protrusion 140 are disposed below the upper ends of the second protrusion 120 and the fourth protrusion 140.

When the pull handle 300 is inverted on the upper blade 10 or when the pull handle 300 is excessively pulled upward, the first engaging convex portion 211 and the second engaging convex portion 221 are respectively the first engaging concave portions. 111 and the upper end of the second engagement recess 121 prevent upward displacement, and the third engagement protrusion 231 and the fourth engagement protrusion 241 respectively include the third engagement recess 131 and the fourth engagement recess 141. Upward displacement is prevented by the upper end of the. The upper displacement of the first to fourth engagement convex portions 211, 221, 231, 241 is prevented at the respective upper ends of the first to fourth engagement concave portions 111, 121, 131, 141, and excessive deformation of the leaf spring 200 is prevented. It is preferably suppressed. It is also permissible to shorten the vertical width of the first to fourth engaging convex portions 211, 221, 231, 241.

When the handle 300 is inverted on the upper blade 10, the covering portion 203 is disposed between the first protrusion 110 and the third protrusion 130 above the upper ends of the first protrusion 110 and the third protrusion 130. The second protrusion 120 and the fourth protrusion 140 are disposed above the upper ends of the second protrusion 120 and the fourth protrusion 140. The time when the handle 300 is inverted on the upper wing plate 10 is basically only when the slide fastener is opened and closed. Accordingly, the covering portion 203 is allowed to be disposed above the upper end of each protrusion during this limited period.

In the present embodiment, the vertical width and the protruding length of the first to fourth engaging convex portions 211, 221 and 231, 241 are completely or substantially equal. This simplifies the design or facilitates the manufacture of the leaf spring 200.

Second Embodiment
The second embodiment will be described with reference to FIGS. 10 to 16. FIG. 10 is an exploded perspective view of the slider, showing a state before the handle is attached to the slider body by a leaf spring. FIG. 11 is a perspective view of the slider and shows a state in which a handle is attached to the slider body by a leaf spring. FIG. 12 is a manufacturing process diagram of the slider, in which the protruding portion before being crimped by the punching tool is indicated by a dotted line, and the protruding portion after being crimped by the punching tool is schematically indicated by a solid line. FIG. 13 is a partial rear view of the slider with the handle lying on the upper wing plate, where the first and second engaging projections of the leaf spring are in contact with the bottom surface of the groove, and the locking claw of the leaf spring is Projects into the element passage. FIG. 14 is a partial cross-sectional schematic diagram of the slider, schematically showing a cross-section along XIV-XIV in FIG. FIG. 15 is a partial cross-sectional schematic diagram of the slider, schematically showing a cross section taken along XV-XV in FIG. FIG. 16 is a schematic cross-sectional view of the slider, showing a state in which the pulling handle is pulled obliquely upward and the pivot shaft portion of the pulling handle is restrained by the third protrusion.

In the present embodiment, unlike the first embodiment, the third protrusion 130 and the fourth protrusion 140 are not provided with the third engagement recess 131 and the fourth engagement recess 141, respectively. Correspondingly, the third engagement convex portion 231 and the fourth engagement convex portion 241 are not provided on the leaf spring 200. In order to compensate for the omission of the engagement structure, the third protrusion 130 and the fourth protrusion 140 are slightly bent toward the first protrusion 110 and the second protrusion 120, respectively, in the present embodiment. The

That is, the third protrusion 130 and the fourth protrusion 140 are provided to be bent toward the first protrusion 110 and the second protrusion 120, respectively, and the third protrusion 130 and the fourth protrusion 140 are respectively provided. And upper end portions 133 and 143 extending toward the first and second protrusions 110 and 120. The distance between the upper end 133 of the third protrusion 130 and the first protrusion 110 is larger than the width of the pivot shaft 310 sandwiched between the first protrusion 110 and the third protrusion 130, and the fourth protrusion The distance between the upper end portion 143 of 140 and the second protrusion portion 120 is larger than the width of the pivot shaft portion 310 sandwiched between the second protrusion portion 120 and the fourth protrusion portion 140. In some embodiments, the distance between the upper end portion 133 of the third protrusion 130 and the first protrusion 110 is such that the pivot shaft portion 310 that is sandwiched between the first protrusion 110 and the third protrusion portion 130 has an interval. The distance between the upper end portion 143 of the fourth protrusion 140 and the second protrusion 120 is larger than the small width, and is smaller than the minimum width of the pivot shaft portion 310 sandwiched between the second protrusion 120 and the fourth protrusion 140. large.

The degree of bending of the third protrusions 130 and the fourth protrusions 140 is moderate. Therefore, the left end portion of the pivot shaft portion 310 can be inserted between the first protrusion portion 110 and the third protrusion portion 130 even after the third protrusion portion 130 and the fourth protrusion portion 140 are plastically deformed. Further, the right end portion of the pivot shaft portion 310 can be inserted between the second protrusion portion 120 and the fourth protrusion portion 140. That is, with the leaf spring 200 not attached to the slider body 100, the pivot shaft portion 310 is inserted between the first protrusion portion 110 and the third protrusion portion 130, and between the second protrusion portion 120 and the fourth protrusion portion 140. Detachable. Even in such a case, it is expected that the same effect as that of the first embodiment is obtained except that an additional caulking process is required for the slider body 100.

As can be understood from FIG. 10, the third protrusion 130 and the fourth protrusion 140 of the slider body 100 are already plastically deformed before the handle 300 is attached to the slider body 100 by the leaf spring 200. Yes. The third protrusion 130 is tilted in an arc shape toward the first protrusion 110 by the action of the punching tool 900 according to FIG. 12, and the upper end of the third protrusion 130 is first than the base of the third protrusion 130. Located on the protrusion 110 side. The fourth protrusion 140 is tilted in an arc toward the second protrusion 120 by the action of the punching tool 900 according to FIG. 12, and the upper end of the fourth protrusion 140 is second than the base of the fourth protrusion 140. Located on the protrusion 120 side. Plastic deformation of the third protrusion 130 and the fourth protrusion 140 is performed by the same punching tool 900. In addition, it is difficult to ensure the protrusion part of the shape after crimping directly by die-casting from the restrictions of a metal mold | die.

Between the first protrusion 110 and the third protrusion 130, a gap W5 larger than the diameter of the cross-sectional circle at the left end of the pivot shaft 310 is provided. Similarly, a space larger than the diameter of the circular cross section of the right end portion of the pivot shaft portion 310 is provided between the second protrusion portion 120 and the fourth protrusion portion 140.

The left end portion of the pivot shaft portion 310 is passed between the first protrusion portion 110 and the third protrusion portion 130, the right end portion of the pivot shaft portion 310 is passed between the second protrusion portion 120 and the fourth protrusion portion 140, Thereafter, attaching the leaf spring 200 to the slider body 100 is the same as in the first embodiment. The behavior of the leaf spring 200 according to the operation of the pull handle 300 is basically the same as that of the first embodiment. However, as can be understood from FIG. 16, when the handle 300 is pulled obliquely upward in front of the upper blade 10, the upper end of the bent third protrusion 130 and the upper end of the fourth protrusion 140 are exclusively pivot shafts. The part 310 is stopped. Since the diagonally upward displacement of the pivot shaft portion 310 is prevented by the third protrusion portion 130 and the fourth protrusion portion 140, the vertical widths of the first engagement protrusion portion 211 and the second engagement protrusion portion 221 are kept low. be able to.

In this embodiment, an additional process is required as compared with the first embodiment, but there is an advantage that the configuration of the slider body 100 and the leaf spring 200 is simplified. Further, in the aspect in which the handle 300 is restrained by the bent protrusion, the mechanical strength of the leaf spring is not a problem.

In the present embodiment, the raised height of the frame portion 17 gradually decreases toward the front, in other words, as the distance from the third protrusion portion 130 and the fourth protrusion portion 140 increases. In the absence of the frame portion 17, the third protrusion portion 130 and the fourth protrusion portion 140 exist as prominent protrusions on the upper blade 10. The above-described frame portion 17 in which the protruding height gradually decreases toward the front has an effect of making the third protrusion portion 130 and the fourth protrusion portion 140 inconspicuous as protrusions.

In the present embodiment, the third projecting portion 130 and the fourth projecting portion 140 are crimped, but the first projecting portion 110 and the second projecting portion 120 may be crimped instead. In this case, the first engagement recess 111 of the first protrusion 110 and the second engagement recess 121 of the second protrusion 120 are omitted, the third engagement recess 131 is provided in the third protrusion 130, and the fourth A fourth engagement recess 141 is provided in the protrusion 140. Further, regarding the leaf spring 200, the first engagement convex portion 211 and the second engagement convex portion 221 are omitted, and a third engagement convex portion 231 and a fourth engagement convex portion 241 are provided instead.

In the present embodiment, the manufacturing process of the slider 400 is also substantially disclosed. Briefly, in the disclosed manufacturing process, one of the first pair of the first protrusion 110 and the second protrusion 120 and the second pair of the third protrusion 130 and the fourth protrusion 140 of the slider body 100 is punched. Bending the other pair side by 900, placing the pivot shaft portion 310 of the handle 300 between the first pair and the second pair, attaching the leaf spring 200 to the slider body 100, A step of preventing the pulling of the handle 300 from the slider body 100 by the spring 200 is included. The reason why the first pair and the second pair are expressed is that the first and second protrusions may be crimped instead of the third and fourth protrusions as described in the previous paragraph. is there.

In the present embodiment, the following manufacturing method is also substantially disclosed. The production method is as follows:
1) a first step of integrally injection-molding at least the upper wing plate 10, the lower wing plate 20, the connecting post 30, and the first to fourth projecting portions 110, 120, 130, and 140;
2) The third protrusion 130 is bent by the punch tool toward the first protrusion 110, and the fourth protrusion 150 is bent by the punch tool toward the second protrusion 120, whereby the first to fourth protrusions are bent. A second step of selectively deforming only the third protrusion part 130 and the fourth protrusion part 140 of the parts 110, 120, 130, 140;
3) After the second step, between the first protrusion 110 and the third protrusion 130 and between the second protrusion 120 and the fourth protrusion 140, between the first protrusion 110 and the third protrusion 130. A third step of inserting and arranging the pivot shaft portion 310 of the pull handle 300 through the opening and the upper opening between the second protrusion portion 120 and the fourth protrusion portion 140;
4) After the third step, a fourth step is included in which the leaf spring 200 is attached to the slider body 100 without deforming the slider body 100 and the leaf spring 200 prevents the puller 300 from being detached from the slider body 100.

<Third Embodiment>
A third embodiment will be described with reference to FIGS. 17 to 19. FIG. 17 is a perspective view of the slider, showing a state in which a handle is attached to the slider body by a leaf spring. FIG. 18 is a top view of the slider, and shows a state in which the handle has fallen on the upper wing plate of the slider body. FIG. 19 is a perspective view of the slider body of the slider.

In the present embodiment, the third and fourth engaging recesses 131 and 141 provided in the third and fourth protrusions 130 and 140 are provided on the opposite side in the front-rear direction compared to the case of the first embodiment. In short, in the first embodiment, the third and fourth engaging recesses 131 and 141 are provided on the front side of the third and fourth projecting portions 130 and 140. On the other hand, in this embodiment, the 3rd and 4th engagement recessed parts 131 and 141 are provided in the back side of the 3rd and 4th projection parts 130 and 140. FIG.

In the present embodiment, the first and third engaging recesses 111 and 131 are recessed from the rear to the front in the front-rear direction with respect to the first and third protrusions 110 and 130 arranged in the front-rear direction. Similarly, the second and fourth engaging recesses 121 and 141 are recessed from the rear to the front with respect to the second and fourth protrusions 120 and 140 arranged in the front and rear direction.

According to this embodiment, after inserting the pivot shaft portion 310 of the handle 300 between the first protrusion portion 110 and the third protrusion portion 130 of the slider body 100 and between the second protrusion portion 120 and the fourth protrusion portion 140. The first to fourth engaging protrusions 211, 221 231 and 241 of the leaf spring 200 are respectively connected to the first to fourth engaging recesses 111 of the first to fourth protrusions 110, 120, 130 and 140, respectively. 121, 131, 141 can be easily fitted, and in this fitting process, the passive portion 201 of the leaf spring 200 is not greatly deformed, and the leaf spring 200 has good strength even after the leaf spring 200 is mounted. Secured. Deterioration of the spring property due to excessive bending of the leaf spring 200 and damage to the leaf spring 200 are preferably avoided.

In the present embodiment, the third projecting portion 130 and the fourth projecting portion 140 include raised portions 135 and 145 extending toward the front end portion of the upper blade 10. The height of the raised portions 135 and 145 gradually decreases toward the front end portion of the upper blade 10. In other words, the protruding portion includes a raised portion connected to the column portion, and this reduces the degree of protrusion of the protruding portion. The first protrusion 110 and the second protrusion 120 are not provided with a raised portion that extends toward the rear end of the upper blade 10 in order to avoid interference with the handle 300.

1st thru | or 4th engagement recessed part 111,121,131,141 is provided in the left-right center side and back side of the 1st thru | or 4th projection part 110,120,130,140. In this case, in particular, the third and fourth engagement recesses 131 and 141 are not exposed to the outside, the smoothness of the outer surface of the slider body 100 is ensured, and clothes are prevented from being caught on the slider 400.

The distance W21 between the first side surface 111a of the first engagement recess 111 and the first side surface 121a of the second engagement recess 121 is equal to the first side surface 131a of the third engagement recess 131 and the first side surface of the fourth engagement recess 141. It is larger than the interval W22 of 141a. The slider body 100 can be manufactured using a slide core. Unlike the first embodiment, the first and second side surfaces 131 a and 131 b of the third engagement recess 131 extend vertically upward from the bottom surface of the groove 16. The first and second side surfaces 141 a and 141 b of the fourth engagement recess 141 extend vertically upward from the bottom surface of the groove 16.

The first side surface 111a of the first engagement recess 111, the first side surface 121a of the second engagement recess 121, the first side surface 131a of the third engagement recess 131, and the first side surface 141a of the fourth engagement recess 141 are: Both are side surfaces orthogonal to the left-right direction. The first side surface 131 a of the third engagement recess 131 is disposed on the inner side in the left-right direction as compared with the first side surface 111 a of the first engagement recess 111. The first side surface 141 a of the fourth engagement recess 141 is disposed on the inner side in the left-right direction as compared with the first side surface 121 a of the second engagement recess 121. The interval W22 between the first side surface 131a of the third engagement recess 131 and the first side surface 141a of the fourth engagement recess 141 disposed relatively forward is relatively the first engagement recess 111 disposed rearward. The distance W21 between the first side surface 111a and the first side surface 121a of the second engagement recess 121 is narrower. It will be understood by those skilled in the art that the above-described planes can be formed using a slide core.

The second side surface 111b of the first engagement recess 111, the second side surface 121b of the second engagement recess 121, the second side surface 131b of the third engagement recess 131, and the second side surface 141b of the fourth engagement recess 141 are: Both are side surfaces orthogonal to the front-rear direction. The second side surface 111b of the first engagement recess 111 and the second side surface 121b of the second engagement recess 121 exist in a common first plane orthogonal to the axis extending in the front-rear direction. The second side surface 131b of the third engagement recess 131 and the second side surface 141b of the fourth engagement recess 141 exist in a common second plane orthogonal to the axis extending in the front-rear direction.

The upper side surface 111c of the first engagement recess 111, the upper side surface 121c of the second engagement recess 121, the upper side surface 131c of the third engagement recess 131, and the upper side surface 141c of the fourth engagement recess 141 are all in the vertical direction. It exists in a common third plane orthogonal to the vertical direction. The upper side surface 111 c of the first engagement recess 111, the upper side surface 121 c of the second engagement recess 121, the upper side surface 131 c of the third engagement recess 131, and the upper side surface 141 c of the fourth engagement recess 141 are the bottom surfaces of the grooves 16. Is parallel to.

The third protrusion 130 that extends upward from the upper blade 10 includes a pillar part 134 and a raised part 135 that extends forward from the pillar part 134. The column portion 134 extends upward from the bottom surface of the groove portion 16 of the upper blade 10. The raised portion 135 is connected to the front side of the column portion 134, and extends while gradually decreasing in height from there. By connecting the raised portion 135 to the column portion 134, a smooth downward inclined surface 136 that descends forward is formed on the upper surface of the third protrusion 130.

The fourth protrusion 140 can be described in the same manner as the third protrusion 130. The fourth protrusion 140 that extends upward from the upper blade 10 includes a column portion 144 and a raised portion 145 that extends forward from the column portion 144. The column portion 144 extends upward from the bottom surface of the groove portion 16 of the upper blade 10. The raised portion 145 is connected to the front side of the column portion 144, and extends from the forward portion while gradually decreasing the height. By connecting the raised portion 145 to the column portion 144, a smooth downward inclined surface 146 that descends forward is formed on the upper surface of the fourth protrusion 140.

The raised portion 135 of the third protruding portion 130 and the raised portion 145 of the fourth protruding portion 140 extend in parallel from the rear toward the front. The distance in the left-right direction between the raised portion 135 of the third protruding portion 130 and the raised portion 145 of the fourth protruding portion 140 is shown as a distance W23. An interval W23 between the left and right raised portions 135 and 145 is narrower than the above-described interval W21 and is smaller than the above-described interval W22. The interval W23 is secured slightly wider than the maximum left-right width of the spring base 202 of the leaf spring 200.

The side surface on the inner side in the left-right direction of the raised portion 135 of the third protrusion 130 is orthogonal to the second side surface 131 b of the third engagement recess 131. A third step is provided between the laterally inner side surface of the raised portion 135 of the third protrusion 130 and the second side surface 131 b of the third engagement recess 131. The third step is located in front of the first step between the second side surface 111b of the first engagement recess 111 and the first side surface 131a of the third engagement recess 131, and is positioned inward in the left-right direction. Note that the first side surface 131 a of the third engagement recess 131 extends rearward until it reaches the second side surface 111 b of the first engagement recess 111.

The side surface in the left-right direction of the raised portion 145 of the fourth protrusion 140 is orthogonal to the second side surface 141b of the fourth engaging recess 141. A fourth step is provided between the side surface in the left-right direction of the raised portion 145 of the fourth protrusion 140 and the second side surface 141 b of the fourth engagement recess 141. The fourth step is located in front of the second step between the second side surface 121b of the second engagement recess 121 and the first side surface 141a of the fourth engagement recess 141, and is positioned inward in the left-right direction. Note that the first side surface 141 a of the fourth engagement recess 141 extends rearward until it reaches the second side surface 121 b of the second engagement recess 121.

The first protrusion 110 has a first step, the second protrusion 120 has a second step, the third protrusion 130 has a third step, and the fourth protrusion 140 has a fourth step. You can also explain. A 3rd level | step difference is a level | step difference which follows a 1st level | step difference, and is distribute | arranged inside the left-right direction rather than a 1st level | step difference. A 4th level | step difference is a level | step difference which follows a 2nd level | step difference, and is distribute | arranged inside the left-right direction rather than a 2nd level | step difference.

The first side surface 111 a of the first engagement recess 111 extends flatly to the rear end of the upper blade 10. The first side surface 121 a of the second engagement recess 121 also extends flatly to the rear end of the upper blade 10. The first side surface 111a of the first engagement recess 111 and the first side surface 121a of the second engagement recess 121 are parallel. The first side surface 131a of the third engagement recess 131 and the first side surface 141a of the fourth engagement recess 141 are parallel.

In the claims, the same elements, for example, the first to fourth modifiers are used to distinguish the pillars, but this is for convenience only and corresponds to or is limited to the disclosure of the embodiments. There is no purpose to do.

Based on the above teaching, those skilled in the art can make various modifications to the embodiments. Reference signs included in the claims are for reference only and should not be referenced for the purpose of limiting the scope of the claims.

400 slider

100 slider body 200 leaf spring 300 handle

10 Upper wing plate 20 Lower wing plate 30 Connecting pillar

15 Claw hole 205 Locking claw

110 First protrusion 120 Second protrusion 130 Third protrusion 140 Fourth protrusion

111 First engagement recess 121 Second engagement recess 131 Third engagement recess 141 Fourth engagement recess

211 1st engagement convex part 221 2nd engagement convex part 231 3rd engagement convex part 241 4th engagement convex part

Claims (13)

1. A slider body (100) in which an upper blade (10) and a lower blade (20) are connected via a connecting column (30), and a leaf spring (200) attached to the slider body (100); A handle (300) having a pivot shaft (310) sandwiched between the leaf spring (200) and the slider body (100) is provided, and the handle (300) is inverted on the upper blade (10). A fastener in which a locking claw (205) of the leaf spring (200) is displaced upward in a claw hole (15) of the upper wing plate (10) in response to a pivoting operation of the handle (300) A slider (400) for a slider,
   The upper wing plate (10) includes first to fourth protrusions (110, 120, 130, 140), and the first to fourth protrusions (110, 120, 130, 140) include the first protrusions. The leaf spring (200) is disposed between the portion (110) and the second protrusion (120) and between the third protrusion (130) and the fourth protrusion (140). One end of the pivot shaft part (310) is disposed between the protrusion part (110) and the third protrusion part (130), and the second protrusion part (120) and the fourth protrusion part (140). Between the other end of the pivot shaft (310) is provided between,
   The first and second protrusions (110, 120) are respectively provided with first and second engaging protrusions (211, 221) of the leaf spring (200). Joint recesses (111, 121) are provided, and each of the first and second engagement recesses (111, 121) corresponds to each of the first and second engagement protrusions (211 when the handle (300) is pivoted. 221) to determine the upper and lower movable range,
   Furthermore, the third and fourth engaging protrusions (231, 241) of the leaf spring (200) are disposed on the third protrusion (130) and the fourth protrusion (140), respectively. Third and fourth engaging recesses (131, 141) are provided, and each of the third and fourth engaging recesses (131, 141) corresponds to each of the third and fourth when the handle (300) is pivoted. A slider provided to define a movable range above and below the engaging projections (231, 241).
2. The slider according to claim 1, wherein the claw hole (15) is provided between the first projecting portion (110) and the second projecting portion (120). 111, 121, 131, 141) have upper stop surfaces (111c, 121c, 131c, 141c) for restricting the upward displacement of the first to fourth engaging projections (211, 221, 231, 241), The first engagement recess (111) and the second engagement recess (121) are longer than the third engagement recess (131) and the fourth engagement recess (141). 121c, 131c, 141c) and a slider extending toward the upper blade (10).
3. When the handle (300) falls on the upper blade (10), there is a first clearance between the upper end of the first engagement recess (111) and the first engagement protrusion (211). A second clearance exists between the upper end of the second engagement recess (121) and the second engagement protrusion (221), and the upper end of the third engagement recess (131) and the third A third clearance exists between the engaging convex portions (231), and a fourth clearance exists between the upper end of the fourth engaging concave portion (141) and the fourth engaging convex portion (241). ,
   The slider according to claim 1 or 2, wherein the first and second clearances are larger than the third and fourth clearances when the handle (300) falls on the upper wing plate (10).
4. The first engagement recess (111) is recessed inward in the left-right direction of the first protrusion (110), and the second engagement recess (121) is in the left-right direction of the second protrusion (120). The third engaging recess (131) is recessed inward in the left-right direction of the third protrusion (130), and the fourth engaging recess (141) is recessed in the fourth protrusion. The slider according to any one of claims 1 to 3, wherein the slider is recessed on the inner side in the left-right direction of (140).
5. The first engagement recess (111) is released backward, the second engagement recess (121) is released backward, the third engagement recess (131) is released forward, and the fourth engagement The slider according to claim 4, wherein the recess (141) is released forward.
6. The first engagement recess (111) is released rearward, the second engagement recess (121) is released rearward, the third engagement recess (131) is released rearward, and the fourth engagement The slider according to claim 4, wherein the recess (141) is released rearward.
7. The distance (W21) between the side surface (111a) orthogonal to the left-right direction of the first engagement recess (111) and the side surface (121a) orthogonal to the left-right direction of the second engagement recess (121) is the third relationship. The gap (W22) between the side surface (131a) perpendicular to the left-right direction of the mating recess (131) and the side surface (141a) perpendicular to the left-right direction of the fourth engagement recess (141) is larger. slider.
8. The third protrusion (130) and the fourth protrusion (140) include a ridge (135, 145) extending toward the front end of the upper blade (10), and the ridge (135, 145). The slider according to claim 1, wherein the height of the slider gradually decreases toward the front end of the upper blade (10).
9. The leaf spring (200) includes a cup-shaped passive portion (201) in which the locking claw (205) is displaced up and down by receiving a force from the rotating pivot shaft portion (310), and the pivot shaft portion. A spring base (202) shaped in a U-shape to keep the passive part (201) in its original position against the force received by the passive part (201) from (310),
   The slider body (100) is provided with a spring accommodating portion (35) extending from the upper blade (10) to the lower blade (20),
   The locking claw (205) is provided at one end of the plate spring (200), and the locked piece (204) stored in the spring storage portion (35) is provided at the other end of the plate spring (200). And
   The passive part (201) includes a first plate part in which the first engaging convex part (211) and the second engaging convex part (221) are provided to protrude oppositely in the left-right direction, and the third part A second plate connecting the first and third plate portions with a third plate portion provided with an engagement convex portion (231) and the fourth engagement convex portion (241) protruding oppositely in the left-right direction. Part
   The leaf spring (200) is bent to have the first to third plate portions,
   The slider according to claim 8, wherein the spring base (202) is coupled to the third plate portion on the side opposite to the second plate portion side.
10. A slider body (100) in which an upper blade (10) and a lower blade (20) are connected via a connecting column (30), and a leaf spring (200) attached to the slider body (100); A handle (300) having a pivot shaft (310) sandwiched between the leaf spring (200) and the slider body (100) is provided, and the handle (300) is inverted on the upper blade (10). A fastener in which a locking claw (205) of the leaf spring (200) is displaced upward in a claw hole (15) of the upper wing plate (10) in response to a pivoting operation of the handle (300) A slider (400) for a slider,
    The upper wing plate (10) includes first to fourth protrusions (110, 120, 130, 140), and the first to fourth protrusions (110, 120, 130, 140) include the first protrusions. The leaf spring (200) is disposed between the portion (110) and the second protrusion (120) and between the third protrusion (130) and the fourth protrusion (140). One end of the pivot shaft part (310) is disposed between the protrusion part (110) and the third protrusion part (130), and the second protrusion part (120) and the fourth protrusion part (140). Between the other end of the pivot shaft (310) is provided between,
    The first and second protrusions (110, 120) are respectively provided with first and second engaging protrusions (211, 221) of the leaf spring (200). Joint recesses (111, 121) are provided, and each of the first and second engagement recesses (111, 121) corresponds to each of the first and second engagement protrusions (211 when the handle (300) is pivoted. 221) to determine the upper and lower movable range,
    Further, the third protrusion (130) and the fourth protrusion (140) are provided to be bent toward the first protrusion (110) and the second protrusion (120), respectively. The protrusion (130) and the fourth protrusion (140) have upper end portions (133, 143) toward the first protrusion (110) and the second protrusion (120), respectively.
    An interval between the upper end (133) of the third protrusion (130) and the first protrusion (110) is sandwiched between the first protrusion (110) and the third protrusion (130). Greater than the width of the pivot shaft (310);
    An interval between the upper end portion (143) of the fourth protrusion portion (140) and the second protrusion portion (120) is sandwiched between the second protrusion portion (120) and the fourth protrusion portion (140). A slider that is larger than the width of the pivot shaft (310).
11. The slider according to any one of claims 1 to 10, wherein the claw hole (15) is provided between the first protrusion (110) and the second protrusion (120). A groove portion (16) is provided on the upper surface of the plate (10), and the bottom surface of the groove portion (16) regulates the downward displacement of the first and second engaging convex portions (211 and 221). A slider that matches
12. The leaf spring (200) includes a cup-shaped passive portion (201) in which the locking claw (205) is displaced up and down by receiving a force from the rotating pivot shaft portion (310), and the pivot shaft portion. The spring base (202) shaped in a U-shape to keep the passive part (201) in its original position against the force received by the passive part (201) from (310) is continuous. The slider according to any one of 1 to 11.
13. A slider body (100) in which an upper blade (10) and a lower blade (20) are connected via a connecting column (30), and a leaf spring (200) attached to the slider body (100); A slider (400) with an automatic stop function comprising a handle (300) having a pivot shaft portion (310) sandwiched between the leaf spring (200) and the slider body (100),
    The upper wing plate (10) includes first to fourth protrusions (110, 120, 130, 140), and the first to fourth protrusions (110, 120, 130, 140) include the first protrusions. The leaf spring (200) is disposed between the portion (110) and the second protrusion (120) and between the third protrusion (130) and the fourth protrusion (140). One end of the pivot shaft part (310) is disposed between the protrusion part (110) and the third protrusion part (130), and the second protrusion part (120) and the fourth protrusion part (140). Between the other end of the pivot shaft (310) is provided between,
    The first and second protrusions (110, 120) are respectively provided with first and second engaging protrusions (211, 221) of the leaf spring (200). Joint recesses (111, 121) are provided, and each of the first and second engagement recesses (111, 121) corresponds to each of the first and second engagement protrusions (211 when the handle (300) is pivoted. 221), the slider (400) manufacturing method provided to define the upper and lower movable ranges,
    A first injection molding of at least the upper wing plate (10), the lower wing plate (20), the connecting column (30), and the first to fourth protrusions (110, 120, 130, 140) is integrally performed. Process,
    The third protrusion (130) is bent by the punch tool toward the first protrusion (110), and the fourth protrusion (150) is bent by the punch tool toward the second protrusion (120). By bending the second projection portion (110, 120, 130, 140), only the third projection portion (130) and the fourth projection portion (140) of the first to fourth projection portions (110, 120, 130, 140) are selectively deformed. Process,
    After the second step, the first protrusions between the first protrusions (110) and the third protrusions (130) and between the second protrusions (120) and the fourth protrusions (140). (110) and the third protrusion (130) and the upper opening between the second protrusion (120) and the fourth protrusion (140) through the upper opening between the third protrusion (130) and the handle (300). A third step of inserting and arranging the pivot shaft (310);
    After the third step, the leaf spring (200) is mounted on the slider body (100) without deforming the slider body (100), and the leaf spring (200) is moved from the slider body (100). A method for manufacturing a slider, comprising a fourth step of preventing the pulling (300) from being detached.

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