WO2015033383A1

WO2015033383A1 - Slide fastener chain, slide fastener, and manufacturing method for slide fastener chain

Info

Publication number: WO2015033383A1
Application number: PCT/JP2013/073633
Authority: WO
Inventors: 剛高荷
Original assignee: Ykk株式会社
Priority date: 2013-09-03
Filing date: 2013-09-03
Publication date: 2015-03-12
Also published as: CN105517460B; CN108936981A; CN108936981B; TWI532445B; JPWO2015033383A1; CN105517460A; TW201526824A; JP6228986B2

Abstract

[Problem] To provide a slide fastener chain and a slide fastener which can be made to be varied in aesthetic appearance in a simple manner for improved decorative quality and in which peeling of transfer foil caused by movement of a slider is reduced, as well as to provide a manufacturing method for a slide fastener chain which can be made to be varied aesthetic appearance in a simple manner and has a high decorative quality. [Solution] A slide fastener chain (1) comprises one pair of fastener tape (2), and a plurality of elements (3) which are each fixed at predetermined intervals on edge portions (21) of each fastener tape (2), said slide fastener chain (1) being characterized in that the elements (3) comprise resin, and on at least a portion of the top (3a), transfer portions (31d) and non-transfer portions (31e) are each formed.

Description

Slide fastener chain, slide fastener, and manufacturing method of slide fastener chain

The present invention relates to a resin-made slide fastener chain, a slide fastener, and a method for manufacturing a slide fastener chain.

Conventionally, there has been a technique for imparting a decorative effect by plating the surface of an element to give a metallic decorative property. However, the plating process has many steps and has a problem of high cost.

Therefore, a technique is disclosed that can give a good decorative property in which the color tone of the material is not visible from the outside by applying a decoration by pressing a thermal transfer film against the element (see Patent Document 1). That is, according to Patent Document 1, it is possible to provide a glossy metallic element simply and efficiently at low cost.

JP-A-8-24019

However, the slide fastener chain including the element decorated by pressing the thermal transfer film has a single color tone on the front side, and it cannot be said that the decorative property is particularly high. Further, in the slide fastener in which the slider is attached to the slide fastener chain, when the slider moves with respect to the element, there is a possibility that the thermal transfer film of the element comes off due to contact with the slider.

The present invention provides a slide fastener chain and a slide fastener that can easily change the aesthetics to enhance the decoration and reduce the peeling of the transfer foil due to the movement of the slider, and a slide fastener that can easily change the aesthetics and have a high decoration. It aims at providing the manufacturing method of the slide fastener chain which manufactures.

A slide fastener chain according to an embodiment of the present invention is a slide fastener chain comprising a pair of fastener tapes and a plurality of elements fixed at predetermined intervals to the edges of each fastener tape, The element is made of resin, and a transfer portion and a non-transfer portion are formed on at least a part of the upper surface.

Further, in the slide fastener chain according to one embodiment of the present invention, the non-transfer portion is made of a part of the base material of the element.

Further, in the slide fastener chain according to one embodiment of the present invention, the transfer portion has a first transfer portion and a second transfer portion arranged with the non-transfer portion interposed therebetween in the left-right direction of the slide fastener chain.

In the slide fastener chain according to an embodiment of the present invention, the transfer portion is formed on the upper surface of the element at a portion where the vertical dimension of the element is reduced.

In the slide fastener chain according to an embodiment of the present invention, the upper surface of the element has an inclined surface inclined downward, and the transfer portion is formed on the inclined surface.

Furthermore, the slide fastener according to an embodiment of the present invention includes the slide fastener chain, a stopper fixed to the edge of the fastener tape at the end of an element row formed by the plurality of elements, and the element And a movable slider for engaging or separating the rows.

Furthermore, the manufacturing method of the slide fastener chain according to one embodiment of the present invention includes a slide fastener chain having a plurality of resin elements fixed at predetermined intervals to the respective edges of the pair of fastener tapes. A manufacturing method, the fixing step of fixing the element to the fastener tape, a transfer step of transferring a transfer foil onto the upper surface of the element after the fixing step, and forming a transfer portion; and the transfer portion And a non-transfer portion forming step of forming a non-transfer portion by cutting a part of the transfer foil.

In the slide fastener chain manufacturing method according to an embodiment of the present invention, the non-transfer portion forming step forms the non-transfer portion by scraping a part of the base material of the element together with the transfer foil.

According to the present invention, the aesthetic appearance is easily changed to enhance the decorativeness, the slide fastener chain and the slide fastener that reduce the peeling of the transfer foil due to the movement of the slider, and the aesthetic appearance is easily changed to be highly decorative. It is possible to provide a method for manufacturing a slide fastener chain for manufacturing a slide fastener.

The perspective view of the slide fastener chain concerning 1st Embodiment is shown. The side view of the slide fastener chain concerning 1st Embodiment is shown. The perspective view which shows the slide fastener chain before the transfer concerning 1st Embodiment is shown. The perspective view which shows the slide fastener chain after the transfer concerning 1st Embodiment is shown. A schematic diagram of a transfer device is shown. 2 shows a partial cross section of a transfer device. A schematic diagram of a polisher is shown. The perspective view of a part of polishing apparatus is shown. A cross-sectional view of a part of the polishing apparatus is shown. The surface where a part of the base material of the element is polished is shown. The front view of the slide fastener using the slide fastener chain concerning 1st Embodiment is shown. The cross section of the state which has arranged the element of a 1st embodiment in a slider is shown. The perspective view of the slide fastener chain of 2nd Embodiment is shown. The side view of the slide fastener chain of 2nd Embodiment is shown. The front view of the other example of the fried fastener chain of embodiment concerning this invention is shown.

Hereinafter, the slide fastener chain 1 will be specifically described with reference to the drawings.

FIG. 1 is a perspective view of a slide fastener chain 1 according to the first embodiment. FIG. 2 is a side view of the slide fastener chain 1 according to the first embodiment.

In the slide fastener chain 1 according to the embodiment of the present invention, the length direction of the fastener tape 2 is the front-rear direction (FB direction) and is indicated by arrows F and B. Further, the width direction of the fastener tape 2 is the left-right direction (LR direction), and is indicated by arrows L and R. Furthermore, the front and back direction of the fastener tape 2 is the vertical direction (UD direction) and is indicated by arrows U and D.

The slide fastener chain 1 includes a pair of left and right fastener tapes 2 and a plurality of synthetic resin elements fixed to opposing edges 21 of each fastener tape 2 at a predetermined interval in the length direction of the fastener tape 2. 3. In addition, the slider mentioned later can mesh or separate the element 3 by moving to the front-back direction of the slide fastener chain 1 along the element 3. FIG.

The fastener tape 2 protrudes from the upper and lower surfaces of the fastener tape 2 and has an edge portion 21 extending in the front-rear direction of the fastener tape 2. The element 3 is integrally formed on the edge 21 of the fastener tape 2 by injection molding a thermoplastic synthetic resin. When the fastener tape 2 is attached to clothes or a bag as a slide fastener, the side that is conspicuous is the upper surface 2a side, and the opposite side is the lower surface 2b side.

The element 3 has a first end located outside the edge 21 of the fastener tape 2 and a second end located inside the edge 21 of the fastener tape 2 in the left-right direction of the slide fastener chain. The element 3 has an upper half 31 disposed on the upper surface 2 a side of the fastener tape 2 and a lower half 32 disposed on the lower surface 2 b side of the fastener tape 2. The upper half part 31 and the lower half part 32 are integrally formed.

The upper half portion 31 has an upper base portion 31a that is in contact with the upper surface 2a of the fastener tape 2, and an upper head portion 31b that protrudes from the upper base portion 31a and extends toward the outside of the fastener tape 2 beyond the edge portion 21. The lower half 32 has a lower base 32a that contacts the lower surface 2b of the fastener tape 2, a lower neck 32c that protrudes from the lower base 32a and extends toward the outside of the fastener tape 2 beyond the edge 21. And a lower head portion 32b formed at the tip of the lower neck portion 32c. The upper base portion 31a and the lower base portion 32a sandwich the edge portion 21 from the vertical direction. The first end of the element 3 is the tip of the upper head 31b and the tip of the lower head 32b.

The upper half 31 of the element 3 is formed with an upper surface 3a continuous over the upper base 31a and the upper head 31b. Of the upper surface 3a, the portion corresponding to the upper surface of the upper head portion 31b is an inclined surface 3a1 inclined downward toward the tip of the upper head portion 31b. On the other hand, a portion corresponding to the upper surface of the upper base portion 31 a in the upper surface 3 a is a flat surface 3 a 2 that is substantially parallel to the upper surface 2 a of the fastener tape 2. However, the upper surface 3a near the second end of the element 3, that is, the upper surface 3a at the end opposite to the side from which the upper head portion 31b protrudes in the upper base 31a is an inclined surface 3a3 inclined downward. The inclined surface 3a3 is preferably a curved surface.

The upper base 31a has a predetermined width dimension in the front-rear direction. The upper head portion 31b is formed so that the dimension in the front-rear direction becomes smaller as the distance from the upper base portion 31a increases. That is, the upper head portion 31b is formed in a tapered shape. Moreover, the front-end | tip of the upper side head 31b is formed smaller in the front-back direction dimension than the lower side head 32b.

The lower base portion 32a has a predetermined width dimension in the front-rear direction. The lower head part 32b is enormous in the front-rear direction. The lower neck portion 32c is formed to have a smaller dimension in the front-rear direction than the lower base portion 32a and the lower head portion 32b. Accordingly, the lower half portion 32 is formed in a constricted shape with the size in the front-rear direction being reduced at the lower neck portion 32c from the lower base portion 32a to the lower head portion 32b.

Due to the shape of the lower half portion 32, when the slide fastener chain 1 moves the slider, the lower head portion 32b and the lower neck portion 32c of the element 3 installed facing the left and right abut each other, It becomes possible to mesh properly.

Further, the upper surface 3a of the element 3 includes a transfer portion 31d to which the transfer foil 33 is attached and a non-transfer portion 31e to which the transfer foil 33 is not attached. As shown in FIG. 2, the transfer part 31d is formed in a part where the vertical dimension of the element 3 is reduced compared to the non-transfer part 31e. That is, the transfer foil 33 includes a first transfer portion 31d1 corresponding to the inclined surface 3a1 of the upper surface 3a of the upper head portion 31b, and a second transfer portion 31d2 corresponding to the inclined surface 3a3 of the upper surface 3a of the end portion of the upper base portion 31a. , Has been transcribed. On the other hand, the non-transfer portion 31e is formed on the flat surface 3a2 of the upper surface 3a formed so that the vertical dimension of the element 3 is constant. Accordingly, the first transfer portion 31d1 and the second transfer portion 31d2 are formed with the non-transfer portion 31e interposed therebetween in the left-right direction of the slide fastener chain.

Next, a method for producing the transfer part 31d of the element 3 will be described.

FIG. 3 is a perspective view showing the slide fastener chain 1 'before transfer. Fig. 4 is a perspective view showing the slide fastener chain 1 "after transfer. Fig. 5 is a schematic view of the transfer device 7. Fig. 6 is a partial cross-sectional portion of the transfer device 7.

As shown in FIG. 5, the transfer device 7 includes a conveying roller 72 and a pressing roller 76 that are arranged to face each other in the vertical direction. The fastener chain sending roll 71 and the transfer film sending roll 74 are arranged on the upstream side of the transporting roller 72 in the transport direction of the fastener chain 1 ′ and the transfer film 34. The transfer film delivery roll 74 is disposed above the fastener chain delivery roll 71. Further, the fastener chain winding bobbin 73 and the transfer film winding bobbin 78 are arranged on the downstream side in the transport direction of the fastener chain 1 ′ and the transfer film 34 with respect to the transport roller 72. The transfer film winding bobbin 78 is disposed above the fastener chain winding bobbin 73. Further, a first guide roller 75 is disposed between the transport roller 72 and the transfer film delivery roll 74. A second guide roller 77 is disposed between the transport roller 72 and the film take-up bobbin 78.

First, the slide fastener chain 1 ′ before transfer is wound around the fastener chain delivery roll 71. The slide fastener chain 1 ′ before transfer is pulled out from the fastener chain delivery roll 71 when the conveying roller 72 is driven. Thereafter, the slide fastener chain 1 ′ before transfer is conveyed between the conveying roller 72 and the pressing roller 76.

The transfer foil 33 is polymerized with a release agent layer or a protective layer (not shown) to form the transfer film 34 shown in FIG. The transfer film 34 including the transfer foil 33 is wound around a transfer film delivery roll 74. The transfer film 34 before transfer is pulled out from the transfer film delivery roll 74 when the conveying roller 72 is driven. Thereafter, the transfer film 34 before transfer passes through the first guide roller 75 and is transported between the transport roller 72 and the pressing roller 76. The pressure roller 76 presses the transfer film 34 before transfer against the slide fastener chain 1 ′ before transfer. The pressing roller 76 incorporates a heater (not shown).

In the transfer film 34, as shown in FIG. 6, the transfer foil 33 is thermally transferred to the upper surface 3a of the element 3 of the slide fastener chain 1 ′ before transfer at a position sandwiched between the conveying roller 72 and the pressing roller 76. . The transferred slide fastener chain 1 ″ is wound around the fastener chain take-up bobbin 73. The remaining film 35 onto which the transfer foil 33 has been transferred passes through the second guide roller 77 and passes through the film take-up bobbin 78. It is wound up.

The transfer film 34 may be the same material as the thermal transfer film described in Patent Document 1 or a different material. Further, the transfer foil 33 does not have to be metallic, and has a color different from the material of the element 3. When the color of the element 3 is black, gold, silver, brown, etc. are adopted as the color of the transfer foil 33.

After the element 3 is fixed to the fastener tape 2, in the slide fastener chain 1 'before transfer, as shown in FIG. 3, the upper surface 3a of the element 3 remains in the state after injection molding. That is, the transfer foil 33 shown in FIG. 1 has not yet adhered to the entire upper surface 3 a of the element 3.

The transfer device 7 shown in FIG. 5 forms a transfer portion 31d in which the transfer foil 33 is attached to the entire upper surface 3a of the element 3 in the slide fastener chain 1 ″ after transfer, as shown in FIG.

Next, a method for forming the non-transfer portion 31e of the element 3 will be described.

FIG. 7 is a schematic view of the polishing apparatus 8. FIG. 8 is a perspective view of a part of the polishing apparatus 8. FIG. 9 is a partial cross-sectional view of the polishing apparatus 8.

The polishing apparatus 8 includes a polishing unit 80 and a transport unit 90.

The polishing unit 80 includes a motor 81, a rotary shaft 82 connected to the motor 81, a plate 83 fixed to the tip of the rotary shaft 82, a protrusion 84 protruding from the plate 83, and a tip of the protrusion 84. And a polishing member 85.

The motor 81 rotates the rotary shaft 82. The rotary shaft 82 has one end connected to the output shaft of the motor 82 and the other end fixed to the plate 83. The rotating shaft 82 may be the output shaft of the motor 82 itself. As shown in FIG. 8, the plate 83 is a circular plate, and a rotation shaft 82 is fixed at the center, and the plate 83 is rotatable about the rotation shaft 82. The protrusion 84 is a member that is attached to the outer peripheral edge of the plate 83 and protrudes in a direction opposite to the rotation shaft 82 from a surface opposite to the surface of the plate 83 to which the rotation shaft 82 is connected. At least one protrusion 84 may be provided, but in the present embodiment, two protrusions 84 are provided symmetrically with respect to the rotation shaft 82. In addition, when providing the some protrusion 84, it is good to install in the circumferential direction of the plate 83 at equal intervals. The polishing member 85 is made of diamond and bonded to the tip of the protrusion 84.

In the polishing unit 80 having such a structure, when the motor 81 is driven, the plate 83 and the protrusion 84 rotate around the rotation shaft 82. Further, it is preferable that the polishing member 85 installed at the tip of the protrusion 84 rotates within a predetermined plane about the rotation shaft 82. The rotational speed of the motor 81 is preferably controllable in the range of 5000 rpm to 10,000 rpm. The protrusion 84 is preferably removable from the plate 83.

The conveyance unit 90 includes a support roller 93 disposed so as to face the polishing member 85 in the vertical direction. And the receiving roller 91 is arrange | positioned rather than the support roller 93 in the conveyance direction upstream of the slide fastener chain 1. FIG. The first pressing roller 92 is disposed to face the receiving roller 91. Further, the polishing chain transport roller 94 is disposed downstream of the support roller 93 in the transport direction of the slide fastener chain 1. The second pressing roller 95 is disposed so as to face the polishing chain conveying roller 94.

The transferred slide fastener chain 1 ″ is conveyed from the receiving roller 91 toward the support roller 93. At this time, the slide fastener chain 1 ″ is sandwiched between the receiving roller 91 and the first pressing roller 92. When the first pressing roller 92 presses the slide fastener chain 1 ″ against the receiving roller 91, a tension acting in a direction opposite to the transport direction is applied. This prevents the slide fastener chain 1 ″ being transported from sagging. .

As shown in FIG. 9, the support roller 93 has a concave receiving groove 93 a that is continuous in the circumferential direction on the outer peripheral surface. In the housing groove 93a, the element 3 of the slide fastener chain 1 "after the transfer is engaged with each other. The fastener tape 2 is disposed so that the back surface 2b faces the outer peripheral surface of the support roller 93. The element 3 is preferably in contact with the bottom surface of the receiving groove 93a.

In this way, when the element 3 is in contact with the bottom surface of the receiving groove 93a, the element 3 receives the vertical force from the polishing member 85 on the bottom surface of the receiving groove 93a when being polished by the polishing member 85. Will be. Accordingly, there is less possibility that the posture of the element 3 is displaced during polishing, and the polishing member 85 can polish the element 3 with high accuracy.

For this reason, as shown in FIG. 9, only the transfer portion 31 d formed on the flat surface 3 a 2 corresponding to the upper surface of the upper base portion 31 a among the transfer portions 31 d formed on the upper surface 3 a of the element 3 contacts the polishing member 85. And polished. Thereby, the non-transfer part 31e becomes a polished surface from which a part of the transfer foil 33 and the element 3 is removed. On the other hand, among the upper surface 3a of the element 3, the first transfer portion 31d1 formed on the inclined surface 3a1 of the upper head portion 31b and the second transfer portion 31d2 formed on the inclined surface 3a3 of the end portion of the upper base portion 31a are It does not contact the polishing member 85 and is not polished.

Further, when the element 3 is accommodated in the accommodation groove 93a, the element 3 is disposed so that the upper surface 3a is exposed from the accommodation groove 93a. The upper surface 3 a is arranged in a posture in which it protrudes from the outer peripheral surface of the support roller 93 more than the upper surface 2 a of the fastener tape 2 in the radial direction of the support roller 93. For this reason, even if the element 3 is in contact with the polishing member 85 and is polished, the surface 2a of the fastener tape 2 does not contact the polishing member 85 as shown in FIG. Therefore, the fastener tape 2 is not damaged due to contact with the polishing member 85.

As described above, the non-transfer portion 31e of the polished slide fastener chain 1 shown in FIG. 1 is formed by grinding the transfer portion 31d by grinding, polishing, cutting, or the like, as shown in FIG. Preferably, the non-transfer portion 31e is formed by grinding at least a part of the base material together with the transfer portion 31d by grinding, polishing, cutting, or the like.

The polished slide fastener chain 1 is nipped and conveyed by the abrasive chain conveying roller 94 and the second pressing roller 95. The conveying speed of the polishing chain conveying roller 94 is preferably controllable. The roller to be driven may be another roller.

FIG. 10 shows a surface where a part of the base material of the element 3 is polished. The surface 31f of the base material of the element 3 indicates a state where the transfer foil 33 is not transferred.

The non-transfer portion 31e may be formed by a surface where a part of the base material of the element 3 is polished. This is because the surface of the base material of the element 3 has some wrinkles and irregularities generated during injection molding. On the other hand, as shown in FIG. 10, the non-transfer portion 31e obtained by polishing a part of the base material has wrinkle-like polishing marks formed from the second end side of the element 3 toward the first end side. And unevenness disappears. Thereby, the non-transfer surface 31e after polishing is formed more smoothly than before polishing. Therefore, it becomes possible to make it more glossy and highly decorative. Furthermore, the transfer portion 31d may be clear-coated before the polishing shown in FIG. By clear-coating the transfer portion 31d, it is possible to form the element 3 with less peeling of the transfer foil 33, and to make it more glossy and highly decorative. Note that, as the clear coating, for example, a paint that is cured by irradiation with ultraviolet rays is used.

FIG. 11 shows the slide fastener 10 of the present embodiment. FIG. 12 shows a cross section in a state in which the element 3 of the first embodiment is arranged in the slider 6.

The slide fastener 10 includes a pair of

fastener tapes

2 and 2, a plurality of elements 3 formed at predetermined intervals along the opposing edge portions 21 of each fastener tape 2, and a plurality of elements 3. At the end of the element row 3 ′, the

fasteners

4 and 5 are fixed to the edge 21 of the fastener tape 2, and the slider 6 is engaged with or separated from the element 3 by moving along the element 3. The element row 3 ′ has a terminal end in the front-rear direction of the slide fastener chain 1. The stopper includes a front stopper 4 disposed at the front end of the element row 3 ′ and a rear stopper 5 disposed at the rear end of the element row 3 ′.

The front stopper 4 is disposed at the front end of each element row 3 ′ of the pair of fastener tapes 2. Only one rear stopper 5 is disposed at the rear end of each element row 3 ′ of the pair of fastener tapes 2. The rear stopper 5 connects the fastener tapes 2 so that the fastener tapes 2 are not separated when the elements 3 are separated. The rear stopper 5 is not limited to the illustrated example. For example, the rear stopper 5 includes an insertion rod fixed to the rear end of the element row of one fastener tape, and a hole that is fixed to the rear end of the element row of the other fastener tape and into which the insertion rod can be inserted. You may have a box provided with. In this case, each fastener tape can be separated together with the separation of the elements. The slider 6 can move in the front-rear direction of the slide fastener chain 1 between the front stopper 4 and the rear stopper 5.

As shown in FIGS. 11 and 12, the slider 6 includes an upper wing plate 61 and a lower wing plate 62 that are arranged facing each other in the vertical direction, a column portion 64 that protrudes from the upper surface 61a of the upper wing plate 61, and a column. A puller 63 connected to the portion 64 is provided. Further, an element passage 65 through which the element 3 can pass is provided between the upper blade 61 and the lower blade 62. The lower surface 61 b of the upper blade plate 61, that is, the surface facing the lower blade plate 62 faces the upper surface 3 a of the element 3 when the element 3 is disposed in the element passage 65.

When the element 3 according to the present embodiment is disposed in the element passage 65 of the slider 6, as shown in FIG. 12, the transfer portion 31 d formed on the upper surface 3 a of the element 3 moves to the lower surface 61 b of the upper blade 61 of the slider 6. Away from. On the other hand, the non-transfer portion 31 e is close to the lower surface 61 b of the upper blade 61 of the slider 6. Therefore, when the slider 6 moves, the transfer portion 31d of the element 3 and the upper blade plate 61 of the slider 6 do not contact each other, but the non-transfer portion 31e and the upper blade plate 61 of the slider 6 may contact each other. However, as shown in FIG. 1, since the transfer stay 33 is not attached to the non-transfer portion 31e, the non-transfer portion 31e of the element 3 and the upper blade 61 of the slider 6 contacted when the slider 6 moved. However, the transfer foil 33 is not peeled off.

FIG. 13 shows a perspective view of the slide fastener chain 1 of the second embodiment. FIG. 14 shows a side view of the slide fastener chain 1 of the second embodiment.

The element 3 of the second embodiment includes a pair of left and right fastener tapes 2 and a plurality of synthetic resin fixed to the edge 21 of each fastener tape 2 at a predetermined interval in the length direction of the fastener tape 2. It has element 3. The element 3 includes an upper half 31 disposed on the upper surface 2 a side of the fastener tape 2, a lower half 32 disposed on the lower surface 2 b side of the fastener tape 2, an upper half 31, and a lower half 32. And an intermediate portion 33 therebetween. The upper half part 31, the lower half part 32, and the intermediate part 33 are integrally formed.

The upper half 31 includes an upper base 31a disposed on the upper surface 2a side of the fastener tape 2, an upper neck 31c protruding from the upper base 31a and extending toward the outside of the fastener tape 2 beyond the edge 21, And an upper head portion 31b formed at the tip of the neck portion 31c. The lower half portion 32 is a lower base portion 32a disposed on the lower surface 2b side of the fastener tape 2, and a lower neck portion that protrudes from the lower base portion 32a and extends toward the outside of the fastener tape 2 beyond the edge portion 21. 32c and a lower head portion 32b formed at the tip of the lower neck portion 32c. The intermediate portion 33 includes an intermediate base portion 33a that contacts the upper surface 2a and the lower surface 2b of the fastener tape 2, an intermediate neck portion 33c that protrudes from the intermediate base portion 33a and extends toward the outside of the fastener tape 2 beyond the edge portion 21, and an intermediate neck portion. An intermediate head 33b formed at the tip of 33c, a recess 33d formed at the tip of the intermediate head 33b, and protrusions 33e formed before and after the intermediate neck 33c.

The intermediate base portion 33a holds the edge portion 21 of the fastener tape 2 from above and below. Further, an upper surface 3a is formed above the upper half 31 so as to extend over the upper base 31a and the upper head 31b.

The upper base 31a has a predetermined width dimension in the front-rear direction. The upper head portion 31b is enormous in the front-rear direction. The upper neck portion 31c is formed to have a smaller size in the front-rear direction than the upper base portion 31a and the upper head portion 31b. Accordingly, the upper half portion 31 is formed in a constricted shape from the upper base portion 31a to the upper head portion 31b with the upper neck portion 31c having a reduced size in the front-rear direction. However, since the width dimension of the upper head part 31b is narrowed toward the upper side, the constriction becomes smaller.

Of the upper surface 3a of the upper half 31, the portion corresponding to the upper surface of the upper head 31b is an inclined surface 3a1 inclined downward toward the tip of the upper head 31b. On the other hand, a portion corresponding to the upper surface of the upper base portion 31 a in the upper surface 3 a is a flat surface 3 a 2 that is substantially parallel to the upper surface of the fastener tape 2.

Further, the upper surface 3a of the element 3 includes a transfer portion 31d to which the transfer foil 33 is attached and a non-transfer portion 31e to which the transfer foil 33 is not attached. As shown in FIG. 12, the transfer part 31d is formed in a part where the vertical dimension of the element 3 is smaller than that of the non-transfer part 31e. That is, the transfer portion 31d is formed on the inclined surface 3a1 corresponding to the upper surface of the upper head portion 31b. On the other hand, the non-transfer portion 31e is formed on the flat surface 3a2 formed so that the vertical dimension of the element is constant. That is, the non-transfer portion 31e is disposed in a portion corresponding to the upper surface of the upper base portion 31a. In this embodiment, the transfer portion is not formed on the inclined surface 3a3 at the end opposite to the side from which the upper head portion 31b protrudes in the upper base portion 31a.

The intermediate base portion 33a has a predetermined width dimension in the front-rear direction, and comes into contact with the edge portion 21 from above and below the fastener tape 2. The intermediate head 33b is enormous in the front-rear direction. The intermediate neck 33c is formed to have a smaller size in the front-rear direction than the intermediate base 33a and the intermediate head 33b. Accordingly, the intermediate portion 33 is formed in a constricted shape from the intermediate base portion 33a to the intermediate head portion 33b with the intermediate neck portion 33c having a reduced size in the front-rear direction.

The recess 33d is formed along the front-rear direction on the tip surface of the intermediate head 33b. The protrusions 33e are formed so as to protrude in the front-rear direction from the front-rear surface of the intermediate neck 33c.

Then, when the intermediate head portion 33b and the intermediate neck portion 33c of the element 3 facing each other are engaged with each other by the slider 6, the protrusions 33e are respectively accommodated in the respective recessed portions 33d facing each other. As described above, each protrusion 33e is accommodated in each of the opposing recesses 33d, so that the engagement state can be firmly maintained even when a force pushing the engagement element 3 in the vertical direction is applied. .

FIG. 15 shows another example of the fried fastener chain 1 according to the embodiment of the present invention.

A part of the slide fastener chain 1 of the example shown in FIG. 15 has a first element row 3 ′ in which a plurality of elements 3 having a transfer portion 31d and a non-transfer portion 31e formed on the upper surface 3a are arranged. The other part of the chain 1 has a second element row 3 ″ in which a plurality of elements 3 whose upper surface 3a is only the transfer portion 31d are arranged. The second element row 3 ″ is compared with the first element row 3 ′. The non-transfer portion 31e may be formed by arranging the elements 3 having a small size. Further, the second element row 3 ″ may be formed by arranging the elements 3 formed only by the non-transfer portion 31e. That is, the slide fastener chain 1 is transferred at predetermined intervals in the front-rear direction. Element rows in which the ratio of the portion 31d and the non-transfer portion 31e are changed may be arranged.

As described above, the slide fastener chain 1 includes the first element row 3 ′ in which the elements 3 in which the transfer portion 31d and the non-transfer portion 31e are formed are arranged, and the element 3 in which the ratio of the transfer portion 31d and the non-transfer portion 31e is changed. By applying the second element row 3 ″ in which are arranged, it is possible to easily change the aesthetics and enhance the decorativeness.

As described above, the slide fastener chain 1 according to the present embodiment includes a pair of fastener tapes 2 and a plurality of elements 3 fixed to the edge portions 21 of the respective fastener tapes 2 at predetermined intervals. 1 and the element 3 is made of resin, and the transfer portion 31d and the non-transfer portion 31e are respectively formed on at least a part of the upper surface 3a. Therefore, it is possible to easily change the appearance and enhance the decorativeness. It becomes.

Further, in the slide fastener chain 1 of the present embodiment, the non-transfer portion 31e is made of a part of the base material of the element 3, so that it can be made glossy and highly decorative.

Further, in the slide fastener chain 1 of the present embodiment, the transfer portion 31d includes the first transfer portion 31d1 and the second transfer portion 31d2 that are arranged with the non-transfer portion 31e interposed therebetween in the left-right direction of the slide fastener chain 1. Therefore, it becomes possible to make it more decorative.

Further, in the slide fastener chain 1 of the present embodiment, the transfer portions 31d, 31d1, and 31d2 are formed on the upper surface 3a of the element 3 at a portion where the vertical dimension of the element 3 is reduced. Foil peeling can be reduced.

In the slide fastener chain 1 of the present embodiment, the upper surface 3a of the element 3 has inclined surfaces 3a1, 3a3 that are inclined downward, and the transfer portions 31d, 31d1, 31d2 are formed on the inclined surfaces 3a1, 3a3. Therefore, peeling of the transfer foil can be effectively reduced while enhancing the decorativeness of the element.

Furthermore, the slide fastener of the present embodiment includes a slide fastener chain 1 and

fasteners

4 and 5 fixed to the edge 21 of the fastener tape 2 at the end of an element row 3 ′ formed by a plurality of elements 3. Since the slider that can move to engage or separate the element row 3 ′ is provided, it is possible to easily change the appearance and to have a high decorative property.

Furthermore, the manufacturing method of the slide fastener chain of the present embodiment includes a slide fastener chain 1 having a plurality of resin-made elements 3 fixed to the respective edge portions 21 of the pair of fastener tapes 2 at a predetermined interval. In the manufacturing method, a fixing step of fixing the element 3 to the fastener tape 2, a transfer step of transferring the transfer foil 33 to the upper surface 3a of the element 3 to form the transfer portion 31d after the fixing step, and a transfer portion 31d A non-transfer portion forming step of forming a non-transfer portion 31e by scraping a part of the transfer foil, so that it is possible to easily manufacture the slide fastener chain 1 with high decorativeness by changing the aesthetic appearance. Become.

In the slide fastener chain manufacturing method of the present embodiment, the non-transfer portion forming step forms the non-transfer portion 31e by scraping a part of the base material of the element 3 together with the transfer foil 33. It becomes possible to make it high.

Although various embodiments of the present invention have been described above, the present invention is not limited to these embodiments, and embodiments configured by appropriately combining the configurations of the respective embodiments also fall within the scope of the present invention. Is.

Claims

A pair of fastener tapes (2);
A slide fastener chain (1) comprising a plurality of elements (3) fixed at predetermined intervals to an edge (21) of each fastener tape (2),
The element (3) is
Made of resin,
A slide fastener chain, wherein a transfer part (31d) and a non-transfer part (31e) are formed on at least a part of the upper surface (3a).
The slide fastener chain according to claim 1, wherein the non-transfer portion (31e) is formed of a part of a base material of the element (3).
The transfer part (31d) has a first transfer part (31d1) and a second transfer part (31d2) arranged with the non-transfer part (31e) in between in the left-right direction of the slide fastener chain. The slide fastener chain according to claim 2.
The slide according to any one of claims 1 to 3, wherein the transfer portion (31d) is formed in a portion of the upper surface (3a) of the element (3) where the vertical dimension of the element (3) is reduced. Fastener chain.
The upper surface (3a) of the element (3) has inclined surfaces (3a1, 3a3) inclined downward, and the transfer portions (31d, 31d1, 31d2) are formed on the inclined surfaces (3a1, 3a3). The slide fastener chain according to claim 4.
A slide fastener chain (1) according to any one of claims 1 to 5,
A fastener (4, 5) fixed to the edge (21) of the fastener tape (2) at the end of an element row (3 ′) formed by the plurality of elements (3);
A slider (6) movable to engage or disengage the element row (3 ');
Slide fastener with
A method for producing a slide fastener chain (1) having a plurality of resin elements (3) fixed at predetermined intervals to respective edges (21) of a pair of fastener tapes (2),
A fixing step of fixing the element (3) to the fastener tape (2);
After the fixing step, a transfer step of transferring the transfer foil (33) to the upper surface (31c) of the element (3) to form a transfer portion (31d);
A non-transfer portion forming step of forming a non-transfer portion (31e) by scraping a part of the transfer foil of the transfer portion (31d);
A method for producing a slide fastener chain, comprising:
The slide fastener chain according to claim 7, wherein the non-transfer portion forming step forms the non-transfer portion (31e) by scraping a part of the base material of the element (3) together with the transfer foil (33). Production method.