JP6518806B2 - Slide fastener slider and slide fastener - Google Patents

Description

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

  Patent Document 1 discloses a slider for a hidden slide fastener. A pull is connected to the slider body through a pull mounting post.

  Patent Document 2 discloses a configuration in which a pull is held in a fallen state when the pull falls forward and backward on the upper blade of the slider. The pair of legs of the pull is individually provided with projections projecting inward in the width direction. The convex portion contacts the pull-tab mounting column in a state where the pull-up is laid down.

  Patent Document 3 discloses that a pull is attached to a metal body by injection molding of a flexible resin material. A shaft is provided on either one of the body and the pull, and a hole through which the shaft is inserted is provided on the other, and the inner peripheral surface of the hole and the outer peripheral surface of the shaft are in close contact.

  Patent Document 4 discloses a technique for fixing a knob in at least one stable position with respect to a cursor by pressing a knob for a slide fastener on a slide.

JP 2007-54176 A Utility model registration 3160840 gazette JP 2005-211200 A JP-A-4-261604

  The present inventors have renewed the significance of providing a more stable pull posture retention in the process of pivoting the pull handle in a manner other than incorporating a mechanism for controlling the pull handle posture in the hidden slide fastener in the slider body. I found it.

A slider for a slide fastener according to an aspect of the present invention includes a lower blade (121), a pair of left and right wall portions (122) provided at left and right side edge portions of the lower blade (121), and A pair of left and right flanges (123) extending inward in the left and right direction from the upper end of the wall (122), a guide post (124) provided on the front end side of the lower blade (121), and A slider body (120) coupled to the upper end and including an upper plate (125) extending rearwardly;
A handle attachment portion (160) provided on the upper plate (125) of the slider body (120);
A slider (100) for a slide fastener comprising a pull (200) attached to said pull attachment (160), wherein
On the basis of the friction between the pull (200) and the pull attachment (160), the pull (200) is in any of the lying posture, the lying posture, and the leaning posture between the lying posture and the lying posture. It is possible to hold the posture.

In some embodiments, the pull (200) includes a stem (210) and a pair of bars (220) extending from each end of the stem (210);
The friction occurs between the pair of bar portions (220) and the pull tab attachment portion (160) and / or the friction occurs between the shaft portion (210) and the pull tab attachment portion (160).

  In some embodiments, the pull tab attachment portion (160) includes a pair of claws (170) that pivotally support the shaft portion (210) of the pull portion (200).

  In some embodiments, the pull (200) has a bend between its proximal end (201) and its free end (202), and when the pull (200) falls back, the pull The portion of the pull (200) extending from the bend towards the free end (202) is inclined obliquely downward.

  In some embodiments, the bend is located closer to the proximal end (201) of the pull (200).

  In some embodiments, the bending angle of the bending portion is in the range of 10 ° to 60 °.

  In some embodiments, the pull (200) includes a flat portion that extends between the bend and the free end (202).

The slide fastener according to one aspect of the present invention comprises a pair of left and right fastener stringers (510) provided with fastener elements (512) at side edges of the fastener tape (511);
A slide fastener comprising a slider (100) for opening and closing the pair of left and right fastener stringers (510), wherein
The slider (100) is
A lower wing (121), a pair of left and right walls (122) provided at left and right side edges of the lower wing (121), and left and right extending inward in the left and right direction from the upper end of the wall (122) A pair of flanges (123), a guide post (124) provided on the front end side of the lower blade (121), and an upper plate (125) connected to the upper end of the guide post (124) and extending rearward. A slider body (120) including
A handle attachment portion (160) provided on the upper plate (125) of the slider body (120);
Comprising a pull (200) attached to said pull attachment (160),
The pull (200) has a bend between its proximal end (201) and its free end (202) and the free end (202) from the bend when the pull (200) falls back. The portion of said pull (200) extending towards) is inclined obliquely downward.

  In some embodiments, the bend is located closer to the proximal end (201) of the pull (200).

  In some embodiments, the pull tab attachment portion (160) includes a pair of claws (170) that pivotally support the shaft portion (210) of the pull portion (200).

  In some embodiments, the bending angle of the bending portion is in the range of 10 ° to 60 °.

  In some embodiments, the pull (200) includes a flat portion that extends between the bend and the free end (202).

  According to an exemplary embodiment of the present invention, stable attitude holding of the pull in the pivoting process of the pull is achieved in a mode other than incorporating a mechanism for controlling the attitude of the pull in the hidden slide fastener in the slider body.

It is a schematic upper surface schematic diagram of the slider concerning one mode of the present invention, and the state where the puller fell to the back is shown. FIG. 6 is a schematic side view schematically showing pivoting of the pull of the slider according to one aspect of the present invention, wherein the shaft of the pull is schematically shown in cross section, and the pull of different pivot positions is schematically represented by a dotted line. Is shown. A pullback which is folded forward, a pullback which is folded backward, a pullback in an inverted state, a pull which is inclined forward, and a pull which is inclined backward are schematically shown by dotted lines. The pull can hold its own posture in a total of five postures. It is a schematic upper surface schematic diagram of the slider concerning one mode of the present invention, and the state where the pull was removed from the pull attachment of a slider barrel is shown for convenience of explanation. A schematic top view of the slider is shown at the top of the drawing and a top view of a portion of the pull at the bottom of the drawing. It is a rough manufacturing process figure of the slider concerning one mode of the present invention, and (a) shows typically the preform before a nail part is crimped, (b) is crimped a nail part. The slider after it is shown schematically. It is a schematic cross section of a concealed slide fastener concerning one mode of the present invention, and an example of a section near the back end part of a slider is shown typically. FIG. 10 is a schematic top view of the slider body before caulking according to one aspect of the present invention, showing that the respective claws extend upward straight before caulking. It is a schematic front view of a slider main part before caulking of a nail part concerning one mode of the present invention. FIG. 6 is a schematic side view of the slider body before caulking according to one aspect of the present invention, showing that the respective claws extend straight upward before caulking. FIG. 5 is a schematic perspective view of a slider pull according to one aspect of the present invention. FIG. 10 is a schematic perspective view of a slider pull according to an aspect of the present invention, viewed from the side opposite to FIG. 9; FIG. 7 is a schematic front view of a slider pull according to one aspect of the present invention. FIG. 5 is a schematic side view of a slider pull according to an aspect of the present invention. It is a schematic upper surface schematic diagram of the slider which concerns on another aspect of this invention, and the state where the puller fell to the back is shown. Fig. 4 schematically shows the slider after the claws according to another aspect of the present invention are crimped.

  Hereinafter, non-limiting exemplary embodiments of the present invention will be described with reference to the drawings. Each feature included in one or more embodiments and embodiments of the disclosure is not individually independent. Those skilled in the art can combine each embodiment and / or each feature without over-explanation, and can also understand the synergistic effect of this combination. Duplicate descriptions between the embodiments will be omitted in principle. The reference drawings are mainly for the description of the invention and may be simplified for the convenience of drawing.

  A non-limiting exemplary embodiment of the present invention will be described with reference to FIGS. FIG. 1 is a schematic top view of the slider, showing a state in which the puller is folded backward. FIG. 2 is a schematic side view schematically showing the pivoting movement of the slider puller, wherein the shaft of the puller is schematically shown in cross section, and the puller at different pivot positions is schematically shown by a dotted line It is done. A pullback which is folded forward, a pullback which is folded backward, a pullback in an inverted state, a pull which is inclined forward, and a pull which is inclined backward are schematically shown by dotted lines. The pull can hold its own posture in a total of five postures. FIG. 3 is a schematic top view of the slider, and for convenience of explanation, the slider is shown with the pull removed from the pull attachment portion of the slider body. A schematic top view of the slider is shown at the top of the drawing and a top view of a portion of the pull at the bottom of the drawing. FIG. 4 is a schematic manufacturing process diagram of the slider, where (a) schematically shows the preform before the claws are crimped, and (b) shows the preform after the claws are crimped The slider is schematically shown. FIG. 5 is a schematic cross-sectional schematic view of the hidden slide fastener, schematically showing an example of a cross section in the vicinity of the rear end portion of the slider. FIG. 6 is a schematic top view of the slider body before caulking of the claws, showing that the claws extend upward straight before caulking. FIG. 7 is a schematic front view of the slider body before caulking of the claws. FIG. 8 is a schematic side view of the slider body before caulking of the claws, and it is shown that each claw extends straight upward before caulking. FIG. 9 is a schematic perspective view of a slider pull. FIG. 10 is a schematic perspective view of the pull of the slider, viewed from the side opposite to FIG. FIG. 11 is a schematic front view of a slider pull. FIG. 12 is a schematic side view of a slider pull.

  In the following description, the front-rear direction, the left-right direction, and the up-down direction are defined as follows. It should be noted that these definitions are provided to enhance the clarity of the disclosure of the specification and should not be used for limiting interpretation of the claimed invention.

  The front-rear direction corresponds to the moving direction of the sliders for opening and closing the left and right fastener stringers. Advancement of the slider closes the left and right fastener stringers, that is, the left and right fastener elements are engaged. Reverse movement of the slider opens the left and right fastener stringers, that is, the left and right fastener elements are disengaged. The left-right direction is a direction orthogonal to the front-rear direction, and is a direction orthogonal to the guide post or connection post of the slider. The up-down direction is a direction orthogonal to the front-rear direction and the left-right direction. The vertical direction is a direction parallel to the guide pillars or the connection pillars of the slider.

  As can be understood from FIGS. 1 to 12 and particularly from FIG. 5, the slider 100 of the illustrated example is a slider for a hidden slide fastener. The present invention should not be limited to the slider for the hidden slide fastener. In another embodiment, the slider 100 is configured as a slider including at least an upper blade, a lower blade, and a connecting post that connects the front end of the upper blade and the front end of the lower blade. Examples of this are illustrated in U.S. Pat. Nos. 5,985,015 and 4,758,015, which are incorporated herein by reference.

  The slider 100 includes a slider body 110 and a pull handle 200. The slider body 110 includes a slider body 120 and a pull attachment portion 160 provided on the slider body 120. The pull 200 is attached to the pull attachment 160.

  The slider body 120 is configured to guide the left and right fastener elements and to engage and disengage the left and right fastener elements in the process of guiding the left and right fastener elements. On the upper surface of the slider body 120, a pull attaching part 160 is provided. The pull tab attachment portion 160 is integrally provided to the slider body 120, but this is not necessarily the case. In another embodiment, the handle attachment portion 160 is separate from the slider body 120 and attached to the slider body 120.

  The slider body portion 120 and the pull handle attachment portion 160 are both made of metal, and the pull handle 200 is made of resin. The pull 200 is relatively soft compared to the slider body 120 and the pull attachment 160. As can be understood by those skilled in the art, the manufacturing process of the slider 100 can include a die casting process, an injection molding process, and a caulking process.

  The pull 200 is an elongated member having a proximal end 201 and a free end 202. The pull 200 includes a shaft 210, a pair of rods 220 extending from each end of the shaft 210, and a grip 230 connected to the pair of rods 220. The shaft portion 210 is circular in cross section, and is elastically deformed by being pressed by the facing surface 177 and the mounting surface 161 of each claw portion 170 as described later.

  More specifically, the shaft portion 210 extends in the left-right direction and extends along the pivot axis AX10 of the pull 200. The axial direction of the shaft portion 210 coincides with the pivot axis AX10 of the pull 200. In the illustrated example, the axial direction of the shaft portion 210 coincides with the left and right direction, but in another embodiment, the axial direction of the shaft portion 210 coincides with another direction, for example, the front-rear direction.

  The pair of bars 220 includes a left bar 221 connected to the left end of the shaft 210 and a right bar 222 connected to the right end of the shaft 210. The left rod 221 and the right rod 222 extend substantially parallel to the direction away from the shaft 210 and the direction away from the pivot axis AX10 of the pull 200. As shown in FIG. 3, a first gap W 220 is provided between the left side bar 221 and the right side bar 222. A second gap W221 is provided between the shaft portion 210 and the grip portion 230.

  The left rod portion 221 and the right rod portion 222 are disposed along the pivot axis AX10 at a first interval W220. A second distance W221 is provided between the shaft portion 210 and the grip portion 230 in the direction orthogonal to the pivot axis AX10, and the second distance W221 is larger than the first distance W220.

  The pull handle 200 is provided with an opening OP 200 surrounded by the shaft portion 210, the left and right rod portions 220, and the grip portion 230. The left and right opening width of the opening OP200 corresponds to the first interval W220 of the left and right bars 220 described above. The opening OP 200 has an opening length between the shaft 210 and the grip 230 that matches the second gap W 221. The opening OP 200 is long in a direction away from the shaft portion 210, and interference with a below-described claw portion 170 that pivotally supports the shaft portion 210 is avoided. The claw portion 170 passes through an opening OP 200 having a first distance W 220 between the pair of rod portions 220 and a second distance W 221 between the shaft portion 210 and the grip portion 230.

  The grip portion 230 is a flat portion provided non-flat so as to make an angle with the direction in which the pair of bar portions 220 extend. The gripping portion 230 is gripped by a human to advance or retract the slider 100. In order to advance the slider 100, the grip portion 230 is gripped by a human and the pull handle 200 is inclined forward. In order to move the slider 100 backward, the grip portion 230 is gripped by a human and the pull handle 200 is inclined rearward. When the pull handle 200 falls forward, the grip 230 extends diagonally upward from the slider body 120, so that the grip 230 does not contact the top surface of the slider body 120, and a space is provided between the two. According to this feature, in the hidden slide fastener, the interference between the U-shaped bent and fixed fastener tape and the grip portion 230 is suppressed or mitigated.

  The specific shape of the pull 200 is arbitrary and should not be limited to the illustrated example. In other embodiments, the gripping portion 230 is provided with one or more arbitrarily sized openings. In another embodiment, the opening OP 200 extends in the vicinity of the free end 202 of the pull 200, and the pull 200 is configured in a light-cut frame.

  In the illustrated example, since the respective rod portions 220 extend in parallel, the lateral width of the pair of rod portions 220 is substantially constant in the direction away from the shaft portion 210. The lateral width of the grip portion 230 gradually decreases as it is separated from the shaft portion 210, and the tip end portion of the grip portion 230 is rounded. These features may be substituted by other features in other embodiments.

  The above-described pull tab mounting portion 160 includes a pair of claw portions 170 that pivotally support the shaft portion 210 of the pull tab 200. The pull tab attachment portion 160 includes a pair of claw portions 170 adjacent to each other with the shaft portion 210 of the pull portion 200 interposed therebetween. In the illustrated example, a pair of claws 170 are arranged in the front-rear direction, and a front claw 171 and a rear claw 172 are provided. The pair of claws 170 are disposed to face each other on the slider body 120. A space is provided between the pair of claws 170, which decreases as it is separated from the slider body 120. In addition, the space | interval of a pair of claw part before caulking shown by Fig.4 (a) maintains a fixed space | interval in an up-down direction.

  The pull attachment unit 160 has a mounting surface 161 between the pair of claws 170, and the shaft 210 is disposed on the mounting surface 161. The mounting surface 161 is a surface that coincides with the upper surface of the slider body 120 or a surface that is at a higher position than the upper surface of the slider body 120. The mounting surface 161 is a substantially flat surface, and is not significantly deformed even in the plastic deformation process of the claw portion 170 shown in FIG. 4.

  Each claw portion 170 has an opposite surface 177 opposite to the other claw portion 170 and an opposite surface 178 opposite to the opposite surface 177. The opposing surface 177 of the front claw 171 rises upward from the front end of the mounting surface 161 and approaches the rear claw 172 in response to the upward elevation. The opposing surface 177 of the rear claw portion 172 rises upward from the rear end of the placement surface 161 and approaches the front claw portion 171 in response to rising upward. That is, the opposing surfaces 177 of the claws 170 approach each other as they are separated from the slider body 120. The shaft portion 210 of the pull 200 is held at three points by the mounting surface 161, the opposing surface 177 of the front claw 171 and the opposing surface 177 of the rear claw 172.

  The opposing surfaces 177 of the front claws 171 and the opposing surfaces 177 of the rear claws 172 are disposed in parallel to each other before caulking of the claws 170, but after caulking of the claws 170, they are not arranged. It is arranged in parallel oppositely.

  A smoothly curved curved surface exists between the opposing surface 177 of the front claw 171 and the mounting surface 161, and a smoothly curved curved surface between the opposing surface 177 of the rear claw 172 and the mounting surface 161. Exist, and each of these curved surfaces is arranged opposite to each other.

  The thickness of each claw portion 170 is defined between the opposite surface 177 and the opposite surface 178 of each claw portion 170. The thickness of the claw portion 170 is reduced on the tip end side of the claw portion 170, and the tip end of the claw portion 170 is rounded when viewed from the direction along the pivot axis AX10 as schematically shown in FIGS. 2 and 4B. Be

  Each claw portion 170 is provided upright on the top surface of the slider body 120. The front claw 171 warps rearward as it extends upward from the top surface of the slider body 120. The rear claws 172 warp forward as they extend upward from the top surface of the slider body 120. Thus, the shaft 210 of the pull 200 is pivotally supported between the pair of claws 170. The shaft portion 210 of the pull 200 is blocked in a direction away from the slider body 120 by the pair of claws 170 on the slider body 120, for example, upward displacement, forward displacement, and backward displacement. Again, in other embodiments, the pair of claws 170 may be arranged laterally rather than longitudinally.

  Each claw 170 has a base 173 and a tip 174. The base portion 173 of the claw portion 170 may be called instead of the lower portion of the claw portion 170, and the tip end portion 174 of the claw portion 170 may be called instead of the upper portion of the claw portion 170. The base portion 173 of the claw portion 170 is connected to the slider body portion 120. The shaft portion 210 of the pull 200 is disposed between the bases 173 of the pair of claws 170. The tip end portion 174 of each claw portion 170 is disposed on the shaft portion 210. The distal end portion 174 of one claw portion 170 and the distal end portion 174 of the other claw portion 170 are disposed close to and opposed to each other on the shaft portion 210. In some embodiments, the distal ends 174 of the claws 170 contact each other on the shaft 210. Since the claws 170 are plastically deformed by caulking, it is also expected that the distance between the tip end portions 174 of the respective claws 170 may vary.

  Each claw portion 170 has different left and right widths at different positions in the extending direction. Ultimately, the base portion 173 of each claw portion 170 is configured to be wide. The tip end portion 174 of each claw portion 170 is configured to be narrow. Ultimately, W173> W174 is satisfied, where W173 indicates the lateral width of the base portion 173 of the claw portion 170, and W174 indicates the lateral width of the tip portion 174 of the claw portion 170. The left and right width corresponds to the width in the axial direction of the shaft portion 210.

  In some embodiments, the claws 170 extend away from the slider body 120 while maintaining a constant lateral width. In some embodiments, as the claws 170 separate from the slider body 120, the lateral width of the claws 170 gradually decreases. In addition to or as an alternative to the embodiments described left, the left and right corner portions 176 of the distal end portion 174 of the claw portion 170 are rounded, whereby the distal end width of the claw portion 170 is continuously reduced below its proximal end width. . In the illustrated example, the left-right width of the tip end portion 174 of the claw portion 170 is reduced from W173 to W174 by the left and right rounded corner portions 176. The left corner portion 176 is on the left end of the shaft portion 210 or in the vicinity thereof, and the right corner portion 176 is on the right end of the shaft portion 210 or in the vicinity thereof. The left end of the shaft portion 210 is a first end, and the right end of the shaft portion 210 is a second end. The left corner portion 176 is a first corner portion, and the right corner portion 176 is a second corner portion.

  The left corner portion 176 of the front claw portion 171 exists between the left side surface 171 m of the front claw portion 171 and the tip surface 171 n of the front claw portion 171. The right corner portion 176 of the front claw portion 171 exists between the right side surface 171 m of the front claw portion 171 and the tip surface 171 n of the front claw portion 171. The left side surface 171m of the front claw portion 171 is included in a first plane in which the pivot axis AX10 is orthogonal. The right side surface 171m of the front claw portion 171 is included in a second plane orthogonal to the pivot axis AX10, and the second plane is parallel to the first plane.

  The left corner portion 176 of the front claw portion 171 is equal to the edge between the left side surface 171 m of the front claw portion 171 and the tip surface 171 n of the front claw portion 171. The right corner portion 176 of the front claw portion 171 is equal to the edge between the right side surface 171 m of the front claw portion 171 and the tip surface 171 n of the front claw portion 171.

  The left corner portion 176 of the rear claw portion 172 exists between the left side surface 172 m of the rear claw portion 172 and the front end surface 172 n of the rear claw portion 172. The right corner portion 176 of the rear claw portion 172 exists between the right side surface 172 m of the rear claw portion 172 and the tip surface 172 n of the rear claw portion 172. The left side surface 172m of the rear claw portion 172 is included in the above-described first plane in which the pivot axis AX10 is orthogonal. The right side surface 172m of the rear claw portion 172 is included in the aforementioned second plane in which the pivot axis AX10 is orthogonal.

  The left corner 176 of the rear claw 172 is equal to the edge between the left side 172 m of the rear claw 172 and the tip surface 172 n of the rear claw 172. The right corner portion 176 of the rear claw portion 172 is equal to the edge between the right side surface 172 m of the rear claw portion 172 and the tip surface 172 n of the rear claw portion 172.

  As described above, each claw portion 170 is held by the pair of rod portions 220 of the pull 200. The base portion 173 of each claw portion 170 is held by the pair of rod portions 220 of the pull 200. Ultimately, when the pull handle 200 falls forward, the front claw portion 171 is held by the pair of rod portions 220. When the pull handle 200 falls backward, the rear claw portion 172 is held by the pair of rod portions 220.

  When the claw portion 170 is held between the pair of bar portions 220, the left bar portion 221 contacts the left side of the claw portion 170, and the right bar portion 222 contacts the right side of the claw portion 170. When the claws 170 are clamped by the pair of rods 220, it is expected that the pair of rods 220 slightly bend. When the claws 170 are held by the pair of rods 220, it is expected that the distance between the pair of rods 220 slightly increases.

  In some embodiments, the distal end 174 of each pawl 170 is pinched by a pair of bars 220 of the pull 200. In some other embodiments, the tip 174 of each pawl 170 is not pinched by the pair of bars 220 of the pull 200.

In some embodiments, W173> W220 is satisfied, where W173 indicates the lateral width of the base 173 of the pawl 170 and W220 indicates the lateral spacing of the pair of bar portions 220 of the pull 200.
In some embodiments, in addition to this condition, W174 ≦ W220 is satisfied, where W174 indicates the lateral width of the tip portion 174 of the claw portion 170, and W220 indicates the pair of rod portions 220 of the pull 200. Indicates the left and right spacing of

  In another embodiment, W174 ≦ W220 is not satisfied. In this case, W174> W220 is satisfied, where W174 indicates the lateral width of the tip end portion 174 of the claw portion 170, and W220 indicates the lateral distance between the pair of rod portions 220 of the pull 200.

  In some embodiments, W173> W220 and W174> W220 satisfy | W173-W220 |> | W174-W220 |.

  The change of the lateral width of the claw portion 170 along with the extension of the claw portion 170 is slow. Thus, in some embodiments, during the entire course of pivoting of the pull 200, the pair of bar portions 220 clamp at least one of the pair of claws 170.

  In the pivoting process of the pull 200, the pair of rod portions 220 passes the boundary between the tip portions 174 of the claw portions 170 disposed opposite to each other on the shaft portion 210. When the pull 200 crosses the boundary of the narrow end portion 174, the friction between the pull 200 and the pull attachment 160 is small, thereby improving the operability of the pull 200.

  More specifically, the pivoting of the pull 200 in the inverted state is required more than the force required to pivot the pull 200 in the collapsed state according to the decrease in the width between the base 173 and the tip 174 of each claw 170 in the axial direction. The power is smaller. It is expected that the pull handle 200 should be switched back and forth obliquely to open and close the fastener stringer rather than laying the pull handle 200 completely down. It is advantageous to make the front and back pivoting of the pull 200 200 relatively light.

  In the fallen state, the bar portion 220 of the pull 200 extends in the front-rear direction. In the inverted state, the pull rod portion 220 extends in the vertical direction. In the fallen state, the rod portion 220 of the pull 200 lies on the slider body 120, assumes a substantially horizontal posture with respect to the upper surface of the slider body 120, or an angle smaller than 30 degrees with respect to this horizontal posture. Take an attitude within the range. In the inverted state, the rod portion 220 of the pull 200 is erected on the slider body 120 and takes a posture substantially perpendicular to the upper surface of the slider body 120 or from 30 degrees on the basis of the vertical posture. Take a posture within a small angle range.

  The force required to pivot the pull 200 in the lying position is the force required to move the pull 200 in the lying and stopped states. The force required to pivot the pull 200 in the inverted state is the force required to move the pull 200 in the inverted and stopped states.

  Note that the pull handle 200 can hold its own posture in a total of five postures illustrated by dotted lines in FIG. This is because the pair of rod portions 220 of the pull 200 grips at least one of the front and rear claws 170. The pivoting of the pull 200 is avoided, and the pivoting of the relatively light pull 200 between oblique positions is ensured.

  In some embodiments, a gap 175 exists between the tip 174 of the front claw 171 and the tip 174 of the rear claw 172. In the illustrated example, the gap 175 extends in the left-right direction and is long in the left-right direction. The gap 175 has a width in the front-rear direction, and the width varies in the left-right direction. As understood from the reference of FIG. 1, the width of the gap 175 near the left and right ends of the shaft portion 210 is larger than the width of the gap 175 near the left and right center of the shaft portion 210. In another embodiment, the tip end portion 174 of the front claw portion 171 and the tip end portion 174 of the rear claw portion 172 may be in direct contact with each other, and the gap 175 may be divided.

  In the present embodiment, each claw portion 170 pivotally supports the shaft portion 210, each claw portion 170 is sandwiched by the pair of rod portions 220 of the pull handle 200, and the width of the claw portion 170 in the axial direction is from the base end side. Is also reduced on the tip side. As a result, while stable support of the pull 200 is secured, good operability of the pull 200 is also achieved. It is avoided or suppressed to adjust the degree of plastic deformation of the claw portion 170 with high accuracy.

  It supplements about the manufacturing method of the slider 100. FIG. The pull 200 can be manufactured, for example, by injection molding. The slider main body 110 to which the pull tab attaching part is crimped, and thereafter, a preform is manufactured by a die casting process. A crimper, eg, a punch, may be used to crimp the slider attachment of the preform, thereby attaching the pull 200 to the slider body 110.

  As shown in FIG. 4, the shaft portion 210 of the pull 200 is disposed between the pair of claws of the pull attachment portion before caulking the preform 1000, and the punch 300 is propelled downward, thereby causing the punch 300 to The claws are plastically deformed by the impact. If the punch 300 descends according to gravity, the degree of plastic deformation of the claws can be adjusted by the weight of the punch 300. The punch surface of the punch 300 includes an axially long semi-cylindrical concave surface, which causes the claws to deform along the arcuate concave surface.

  In the process of caulking the claws, it is expected that the lateral width of the claws slightly fluctuates. That is, the lateral width of the tip of the claw after crimping is wider than the lateral width of the tip of the claw before crimping. It is good to set the dimension of the nail | claw part of preform based on such a viewpoint.

  After caulking the claws, the shaft portion 210 of the pull 200 is held by the slider body 110 at three points. That is, the shaft portion 210 contacts the front claw portion 171, the rear claw portion 172, and the upper plate 125 described later, and is pressed at these contact points.

  FIG. 5 shows a slide fastener 500 according to an embodiment of the present invention, showing that the slider described above is incorporated into the slide fastener 500. As shown in FIG. 5, the slide fastener 500 includes a pair of left and right fastener stringers 510. Each fastener stringer 510 includes a fastener tape 511 and a fastener element 512 attached to the side edge of the fastener tape 511. The slide fastener 500 is a hidden slide fastener. Therefore, the fastener tape 511 is bent and fixed in a U-shape, and it is difficult to visually recognize the slider body 120 from above. Fastener stringer 510 further includes reinforcing tape 513, and fastener element 512 is sewn thereto.

  Although a coil element is illustrated as the fastener element 512, other elements may be employed. In another embodiment, the resin element is integrally provided on the side edge of the fastener tape by injection molding.

  The configurations of the preform 1000 and the handle 200 will be further described with reference to FIGS. 6 to 12. The slider body 110 is adapted for hidden slide fasteners. The slider body 120 includes a lower wing 121, a pair of left and right walls 122 provided at left and right side edges of the lower wing 121, and a pair of left and right flanges 123 extending inward in the left and right direction from the upper end of the wall 122. And a guide post 124 provided on the front end side of the lower blade 121, and an upper plate 125 provided on the upper end of the guide post 124 and projecting rearward. The upper surface of the upper plate 125 is provided with a pull attaching portion 160, that is, a pair of claws 170. A Y-shaped partition 126 branched by the guide post 124 is provided on the upper surface of the lower blade 121, thereby promoting smooth movement of the left and right elements.

  As understood by those skilled in the art, the upper plate 125 protrudes further rearward than the guide post 124. The upper plate 125 also protrudes outward in the left-right direction with respect to the guide post 124. The rear portion of the upper plate 125 is tapered toward the center in the left and right direction, so to speak, the rear portion of the upper plate 125 includes a tapered portion 125 m. A passage for a fastener tape 511 is provided between the tapered portion 125 m and the left and right flange portions 123. This point is immediately understood from the additional reference of FIG.

  A pair of left and right front ports are provided between the left and right walls 122 and the guide pillar 124 for the entry and exit of the left and right elements. The upward displacement of the element is prevented by the projecting portion of the upper plate 125 on the outer side in the lateral direction and the flange portion 123. The rear end of the slider body 120 is provided with a single rear opening through which the left and right elements in meshing condition pass.

  The lower blade 121, the wall 122, the flange 123, the guide post 124, and the upper plate 125 construct a Y-shaped element passage. The backward movement of the slider 100 causes the guide pillars 124 of the slider 100 to disengage the left and right elements in the engaged state, whereby the left and right fastener stringers 510 are opened. The forward movement of the slider 100 causes the left and right elements in the non-engaged state to pass through the guide post 124 and become engaged in this process.

  The pull 200 is bent at one point between the proximal end 201 and the free end 202 of the pull 200 as described above. The degree of flexing is arbitrary. In some embodiments, the gripping portion 230 is connected to the pair of bar portions 220 at an angle in the range of 10 ° to 60 °. The angle which belongs to an angle range of 15 degrees-55 degrees, 20 degrees-50 degrees, 25 degrees-45 degrees, and 30 degrees-40 degrees is also employable.

  In the case of the hidden slide fastener, it is difficult to incorporate a mechanism for controlling the attitude of the pull handle 200 in the slider body 110. In the disclosed embodiment, retention of the attitude of the pull 200 is achieved based on the configuration of the pull 200 and the pull attachment 160, which should be noted in the slider for the hidden slide fastener.

  Another aspect of the present invention will be further described with reference to FIGS. 13 and 14. FIG. 13 is a schematic top view of the slider, showing a state in which the puller is folded backward. FIG. 14 schematically shows the slider after the claws are crimped.

  In the embodiment of the precedent example, each claw portion 170 is held by the pair of rod portions 220 of the puller. On the other hand, in the present embodiment of the following example, the claws 170 are not held by the pair of rod portions 220 of the pull. Also in such an embodiment, since the shaft portion 210 of the pull is held at three points by the mounting surface 161 and the opposing surface 177 of the pair of claws, the easy attachment of the pull is the same as in the previous embodiment. It is possible to achieve stable posture retention of the pull handle during the pivoting process of the pull handle.

  As shown in FIG. 13, the lateral width of the pair of rod portions 220 is larger than the maximum lateral width of each claw portion 170, and thus each claw portion 170 is held between the pair of rod portions 220 in the pivoting process of the pull 200. It will not be done. In addition, it is anticipated that one of a pair of rod parts 220 will contact each nail | claw part 170 and the left side surface or right side of each nail | claw part 170 in the end.

  As shown in FIG. 14, the shaft 210 comes in contact with the opposing surface 177 of the front claw 171, the opposing surface 177 of the rear claw 172, and the mounting surface 161, whereby the shaft 210 is the slider barrel 120. It is held between the pair of claws 170 at the top.

  In FIG. 14, the contact point P5 between the facing surface 177 of the front claw 171 and the shaft 210, the contact point P6 between the facing surface 177 of the rear claw 172 and the shaft 210, and the contact between the mounting surface 161 and the shaft 210 The point P7 is schematically illustrated. The contact points P5 to P7 are arranged circumferentially around the shaft portion 210 at equal angular intervals. Briefly, the contact points P5 to P7 are circumferentially spaced at an angular interval of substantially 120 °. If there are too many contact points, resistance to pivoting of the pull 200 may increase. Those skilled in the art will appreciate that the illustrated three point holding arrangement is beneficial.

  In the illustrated example of FIGS. 13 and 14, W173 <W220 is satisfied, where W173 indicates the lateral width of the base 173 of the claw portion 170, and W220 indicates the left and right of the pair of bar portions 220 of the pull 200. Indicates the interval. Furthermore, W174 <W220 is satisfied, where W174 indicates the lateral width of the tip end portion 174 of the claw portion 170, and W220 indicates the lateral spacing of the pair of rod portions 220 of the pull 200.

  Given the above teachings, various modifications can be made to the embodiments by those skilled in the art. The reference numerals included in the claims are for reference and should not be referred to for the purpose of limiting the scope of the claims.

Reference Signs List 100 slider 110 slider body 120 slider body 160 pull handle attaching portion 170 claw portion

200 pull handle 210 shaft 220 rod

Claims (10)

A lower wing (121), a pair of left and right walls (122) provided at left and right side edges of the lower wing (121), and left and right extending inward in the left and right direction from the upper end of the wall (122) A pair of flanges (123), a guide post (124) provided on the front end side of the lower blade (121), and an upper plate (125) connected to the upper end of the guide post (124) and extending rearward. A slider body (120) including
A handle attachment portion (160) provided on the upper plate (125) of the slider body (120);
A slider (100) for a slide fastener comprising a pull (200) attached to said pull attachment (160), wherein
The pull tab attachment portion (160) includes a pair of claw portions (170) pivotally supporting a shaft portion (210) of the pull portion (200);
On the basis of the friction between the pull (200) and the pull attachment (160), the pull (200) is in any of the lying posture, the lying posture, and the leaning posture between the lying posture and the lying posture. The slider is capable of holding the attitude. The pull (200) includes front Kijiku portion a pair of rods extending from each end of the (210) and (220),
The friction occurs between the pair of bar portions (220) and the pull tab attachment portion (160) and / or the friction occurs between the shaft portion (210) and the pull tab attachment portion (160). The slider according to claim 1. The pull (200) has a bend between its proximal end (201) and its free end (202) and the free end (202) from the bend when the pull (200) falls back. The slider according to claim 1 or 2 , wherein the portion of the pull (200) extending towards) is inclined obliquely downward. The slider according to claim 3 , wherein the bending portion is provided near a proximal end (201) of the pull (200). The bending angle of the bent portion is included in the range of 10 ° to 60 °, the slider according to claim 3 or 4. The slider according to any one of claims 3 to 5 , wherein the pull (200) comprises a flat portion extending between the bend and the free end (202). A pair of left and right fastener stringers (510) provided with fastener elements (512) at side edges of the fastener tape (511);
A slide fastener comprising a slider (100) for opening and closing the pair of left and right fastener stringers (510), wherein
The slider (100) is
A lower wing (121), a pair of left and right walls (122) provided at left and right side edges of the lower wing (121), and left and right extending inward in the left and right direction from the upper end of the wall (122) A pair of flanges (123), a guide post (124) provided on the front end side of the lower blade (121), and an upper plate (125) connected to the upper end of the guide post (124) and extending rearward. A slider body (120) including
A handle attachment portion (160) provided on the upper plate (125) of the slider body (120);
Comprising a pull (200) attached to said pull attachment (160),
The pull tab attachment portion (160) includes a pair of claw portions (170) pivotally supporting a shaft portion (210) of the pull portion (200);
On the basis of the friction between the pull (200) and the pull attachment (160), the pull (200) is in any of the lying posture, the lying posture, and the leaning posture between the lying posture and the lying posture. It can hold the attitude,
The pull (200) has a bend between its proximal end (201) and its free end (202) and the free end (202) from the bend when the pull (200) falls back. The slide fastener in which the portion of the pull (200) extending toward the) is inclined downward. The slide fastener according to claim 7 , wherein the bending portion is provided near a proximal end (201) of the pull (200). The slide fastener according to claim 7 or 8 , wherein a bending angle of the bending portion is included in a range of 10 ° to 60 °. The slide fastener according to any one of claims 7 to 9 , wherein the pull (200) includes a flat portion extending between the bent portion and the free end (202).

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