TW201509335A - Core thread providing apparatus of continuous element row forming apparatus for slide fastener - Google Patents

Abstract

A core thread providing apparatus of a coil element forming apparatus is provided, wherein a core thread bobbin can be easily changed and productivity is thus increased. The core thread providing apparatus 10 includes: a first driving axis 25a and a second driving axis 25b rotatably supported by facing side wall 21a and side wall 21b respectively; and a bobbin supporting portion 30 disposed between the first driving axis 25a and the second driving axis 25b. Moreover, the bobbin supporting portion 30 includes a bobbin holder 33; a base portion of the bobbin holder 33 is mounted at the first driving axis 25a via a hinge portion 65; the bobbin holder 33 can use the hinge portion 65 as a center to rotate a front end portion of the bobbin holder 33 in a direction which is away from the first driving axis 25a or the second driving axis 25b.

Description

Core supply device for continuous chain sprocket forming device for zipper

The present invention relates to a core wire feeding device for a continuous fastener element forming device for a slide fastener.

As a conventional continuous chain element forming device for a slide fastener, there is known a device in which a winding wire is wound by winding a monofilament in a coil shape via a mandrel. The core wire supply device of the continuous chain element forming device for the slide fastener is known, and the core wire supply device includes a bobbin support portion for supporting a core wire wound with a core wire. The bobbin; the guide portion for the core wire is disposed close to the bobbin support portion, and is guided by the outer circumference of the core bobbin to eject the core wire (for example, see Patent Document 1). Moreover, the bobbin support portion includes a pair of conical chucks and a spring that presses one of the chucks toward the other chuck, and the core bobbin is clamped by the spring pressure of the spring. Between a pair of chucks.

[Previous Technical Literature]

[Patent Literature]

[Patent Document 1] British Patent No. 1315021

However, in the core wire supply device described in Patent Document 1, when the core bobbin is replaced, one of the chucks is moved in a direction away from the other chuck against the spring pressure of the spring, and the weight is relatively large. The replacement of the core bobbin has a large burden on the operator and the replacement work is cumbersome. Further, since the monofilament is present around the core bobbin, the operator must replace the core bobbin in such a manner as to avoid contact with the monofilament and prevent the dirt or the like from adhering to the core wire of the core bobbin, and the replacement work takes time, so that there is production. The possibility of reduced sex.

The present invention has been made in view of the above circumstances, and an object of the invention is to provide a core wire supply device for a continuous fastener element molding device for a slide fastener, which can easily replace a core bobbin and improve productivity.

The above object of the present invention is achieved by the following constitution.

(1) A core wire feeding device for a continuous sprocket forming device for a slide fastener, comprising: a housing having a pair of opposite side walls; the first drive shaft and the second drive shaft being rotatably respectively Supporting the side wall; the bobbin support portion is disposed between the first drive shaft and the second drive shaft, and supports the core bobbin wound with the core wire; the core wire guide portion is rotated around the outer circumference of the core bobbin to guide the core bobbin The core wire and the filament guiding portion are respectively disposed on the first driving shaft and the second driving shaft, and guide the monofilament; and the core wire supplying device is characterized in that the bobbin supporting portion includes a bobbin holder. The base end portion of the bobbin holder is attached to the first portion via a hinge portion The drive shaft or the second drive shaft, the bobbin holder can rotate the front end portion of the bobbin holder in a direction away from the first drive shaft or the second drive shaft centering on the hinge portion.

(2) The core wire supply device of the continuous chain element forming device for a slide fastener according to the above aspect, wherein the bobbin support portion includes: a first portion rotatably supported by the first drive shaft; and a second portion rotatable The ground is supported by the second drive shaft; and the connecting plate connects the first portion and the second portion; and the hinge portion is attached to the first portion or the second portion.

(3) The core wire feeding device of the continuous sprocket forming device for a slide fastener according to the above aspect, wherein the hinge portion includes a rotating portion including a rotating shaft, and a pair of shaft supporting portions disposed on both sides of the rotating portion. a rotating shaft is inserted; and a locking mechanism; and the locking mechanism includes: a first fastening hole provided in the rotating portion; a second fastening hole provided in the pair of shaft supporting portions; and a locking pin (pin) When the lock mechanism is locked, it is inserted into the first fastening hole and the second fastening hole.

(4) The core wire supply device of the continuous sprocket forming device for a slide fastener according to the above aspect, wherein the lock mechanism includes a pin support portion that can slide the lock pin in parallel with the rotation axis support.

(5) The core wire supply device for a continuous sprocket forming device for a slide fastener according to (3) or (4), further comprising a bracket fixed to a side wall of the housing on a side where the hinge portion is provided And extending to the side wall opposite to the side wall, and forming a third fastening hole in the bracket, the third fastening hole is configured to lock the locking pin from the first fastening hole of the locking mechanism when the locking mechanism is unlocked 2 When the snap hole is pulled out and moved, the lock pin is inserted.

(6) The core wire supply device of the continuous chain element forming device for a slide fastener according to any one of the aspects of the present invention, wherein a guide support portion is detachably provided at a front end portion of the bobbin holder, The guide support portion rotatably supports the guide portion for the core wire.

According to the core wire supply device for forming a wound element of the present invention, the base end portion of the bobbin holder of the bobbin support portion is attached to the first drive shaft or the second drive shaft via the hinge portion, and the bobbin holder can be The hinge portion is centered, and the front end portion of the bobbin holder is rotated in a direction away from the first drive shaft or the second drive shaft. Therefore, the bobbin holder can be swung around the rotation axis of the hinge portion. Therefore, in a state where the bobbin holder is swung, only the core bobbin can be inserted and removed with respect to the bobbin holder, so that the replacement of the core bobbin can be easily performed. In addition, the replacement time can be shortened, so that the productivity of the wound sprocket can be improved.

10‧‧‧core supply device

20‧‧‧shell

21a, 21b‧‧‧ side wall

25a‧‧‧1st drive shaft

25b‧‧‧2nd drive shaft

25c‧‧‧Fixed shaft

26‧‧‧through holes

30‧‧‧Bob tube support

31a‧‧‧1st side panel (part 1)

31b‧‧‧2nd side panel (part 2)

32‧‧‧Link board

33‧‧‧Bob tube holder

34‧‧‧Parts Department

35‧‧‧ pole

36‧‧‧Bob guide plate

45‧‧‧Guideline for core wire

45a‧‧‧1st core wire insertion hole

45b‧‧‧2nd core wire insertion hole

45c‧‧‧Guidance

46‧‧‧balance department

50‧‧‧guide support

51‧‧‧ fitting convex

55a‧‧‧1st filament guide

55b‧‧‧2nd filament guide

56‧‧‧ filament insertion hole

57a, 57b‧‧‧balance

60‧‧‧ bracket

60a‧‧‧3rd snap hole

65‧‧‧ Hinge section

66‧‧‧Axis support

66a, 67a‧‧‧ shaft insertion holes

67‧‧‧Rotating Department

68‧‧‧Rotary axis

75‧‧‧Locking mechanism

76a‧‧‧1st snap hole

76b‧‧‧2nd snap hole

77‧‧‧Lock pin

77a‧‧‧Operating film

78‧‧‧ pin support

78a‧‧‧1st pin insertion hole

78b‧‧‧2nd pin insertion hole

79‧‧‧Hanging bolts

80‧‧‧core buffer mechanism

81‧‧‧Base section

82‧‧‧Tensile adjustment department

83‧‧‧ Guide rod

84‧‧‧ pulley

100‧‧‧Rolling sprocket forming device (continuous sprocket forming device for zipper)

101‧‧‧ mandrel

102‧‧‧ screw

B‧‧‧core bobbin

L1‧‧‧The center axis of rotation of the first drive shaft

L2‧‧‧Rotational central axis of the 2nd drive shaft

M‧‧‧ monofilament

S‧‧‧ core wire

Fig. 1 is a front elevational view showing a continuous chain element forming device for a slide fastener according to an embodiment of a core wire supplying device of the present invention.

Fig. 2 is a plan view showing the core wire supply device shown in Fig. 1;

Fig. 3 is an enlarged perspective view showing a main part of the hinge portion shown in Fig. 2;

Fig. 4 is an enlarged front elevational view showing the state at the time of locking of the lock mechanism.

Fig. 5 is an enlarged front elevational view showing a state in which the lock mechanism is unlocked.

Fig. 6 is a plan view showing a state in which the lock mechanism is unlocked and the bobbin support portion is swung.

Fig. 7 is a front elevational view showing a state in which the bobbin support portion is swung to remove the guide support portion.

Hereinafter, an embodiment of the core wire supply device of the wound sprocket forming device (continuous sprocket forming device for slide fastener) of the present invention will be described in detail based on the drawings. In the following description, in the winding element forming device, the direction in which the following winding element rows are formed and discharged is referred to as the rear side, and the opposite direction is referred to as the front side, and the front side is set as shown in FIG. The paper surface is on the left side, and the rear side is set to the right side with respect to the paper surface of FIG. The front-rear direction is parallel to the axial direction when the monofilaments described below are wound around the core wire in a wound shape. In the vertical and horizontal directions orthogonal to the front-rear direction, the upper side is set to the upper side with respect to the paper surface of FIG. 1, the lower side is set to the lower side with respect to the paper surface of FIG. 1, and the left side is set to be close to the paper surface of FIG. The front side and the right side are set to be deep sides with respect to the paper surface of Fig. 1 . In addition, the left-right direction is aligned with the left side and the right side in a state in which the upper and lower sides are aligned, as viewed from the rear side toward the front side. Further, the front-rear direction of the winding element forming device is also referred to as the longitudinal direction of the bobbin holder. Further, the left-right direction of the wound element forming device is also referred to as the width direction of the bobbin holder. Further, the vertical direction of the wound element forming device is also referred to as the height direction of the bobbin holder. Here, the left-right direction of the wound element forming device is parallel to the horizontal plane, and the vertical direction is a vertical direction perpendicular to the horizontal plane, and is parallel to the direction in which gravity acts.

The winding element forming apparatus 100 of the present embodiment conveys both the core wire S and the monofilament M in a synchronized state, and the winding element is formed by winding the monofilament M in a wound shape around the core wire S by using the mandrel 101. . Further, the monofilament M is continuously wound around the bobbin, the bobbin is placed on the front side of the winding element forming device 100, the monofilament M is introduced into the winding element forming device 100, and the monofilament M and the roll are placed. The core wire S of the core wire supply device 10 provided in the sprocket molding device 100 is introduced into the winding sprocket molding portion, whereby The wound element is wound in a wound shape around the core wire S, and is continuously discharged from the winding element forming device 100. The winding sprocket row is also referred to as a continuous sprocket row.

As shown in FIG. 1, the wound sprocket forming apparatus 100 includes a rod-shaped spindle 101 extending in the front-rear direction, a pair of screws 102 disposed on both sides of the spindle 101, and a core supply device 10. The core bobbin B is held inside, and both the core wire S and the monofilament M are supplied to the mandrel 101 side in a synchronized state, and the core bobbin B is wound with the core wire S on the outer peripheral surface. The core bobbin B is wound with a core wire S around a hollow cylindrical portion having a predetermined diameter, and the core wire S includes a twisted wire formed by bundling a plurality of wires. Further, the core wire S is a twisted wire only as an example.

As shown in FIGS. 1 and 2, the core wire supply device 10 includes a casing 20 including a pair of side walls 21a and a side wall 21b facing in the front-rear direction, and a first drive shaft 25a and a second drive shaft 25b, respectively rotatable. The ground support is supported by the pair of side walls 21a and the side wall 21b; the bobbin support portion 30 is disposed between the first drive shaft 25a and the second drive shaft 25b, and supports the core bobbin B; the core guide portion 45 is provided in the core tube The outer circumference of the tube B is rotated to guide the core wire S of the core bobbin B; the guide support portion 50 is rotatably supported by the core guide portion 45; and the first filament guide portion 55a and the second filament guide The portion 55b is provided on the first drive shaft 25a and the second drive shaft 25b, respectively, and guides the monofilament M conveyed toward the spindle 101.

The first drive shaft 25a and the second drive shaft 25b rotate around an axis extending in the front-rear direction. Further, the mandrel 101 is disposed along the axial center direction, and the front end of the front side of the mandrel 101 extends toward the front side of the side wall 21a. The core wire guide portion 45 extends from the central axis of the guide support portion 50 in the vertical direction or the left-right direction. In addition, the first filament guide portion 55a and the second filament guide portion 55b extend in the vertical direction or the left-right direction from the central axis of the first drive shaft 25a or the second drive shaft 25b. Here, the core The wire guide portion 45, the filament guide portion 55a, and the filament guide portion 55b have a flat shape in which the dimension in the vertical direction and the left-right direction is larger than the dimension in the front-rear direction, and the core wire S or the monofilament M is held at the tip end thereof. It is called a guide arm 45 for a core wire, a guide arm 55a for filaments, and a guide arm 55b for filaments. A balance portion 57a and a balance portion 57b are attached to the first drive shaft 25a and the second drive shaft 25b. The balance portion 57a, the balance portion 57b, the first filament guide portion 55a, and the second filament are attached to the first drive shaft 25a and the second drive shaft 25b. The guide portion 55b extends symmetrically with respect to the central axes of the first drive shaft 25a and the second drive shaft 25b. The balance portion 57a and the balance portion 57b have a flat plate shape similarly to the first filament guide portion 55a and the second filament guide portion 55b, and are used to make the load applied to the central axis during rotation uniform. Further, the balance portion 57a and the balance portion 57b may not be required.

The first drive shaft 25a is a columnar member, and its outer peripheral surface is rotatably supported by the front side wall 21a via a bearing (not shown). The second drive shaft 25b is a cylindrical member, and its outer peripheral surface is rotatably supported by the rear side wall 21b via a bearing (not shown). Further, the first drive shaft 25a and the second drive shaft 25b are provided to rotate in synchronization with each other by a motor (not shown) and a power transmission mechanism.

The first filament guide portion 55a is attached to the first drive shaft 25a, and the first filament guide portion 55a is a thin plate-shaped member having a width direction smaller than the height direction, and is in the axial direction of the first drive shaft 25a ( It also extends from the first drive shaft 25a in the vertical direction in the front-rear direction. A filament insertion hole 56 through which the filament M is inserted is formed in one end portion of the first filament guide portion 55a so as to penetrate therethrough. The second filament guide portion 55b of the thin plate-like member similar to the first filament guide portion 55a is attached to the second drive shaft 25b. A filament insertion hole 56 through which the filament M is inserted is formed in one end portion of the second filament guide portion 55b so as to penetrate therethrough. In addition, the first filament guide portion The 55a and the second filament guide portions 55b are set to rotate in the same phase. When the first filament guide portion 55a and the second filament guide portion 55b are rotated, the filament M passing through the filament insertion hole 56 is rotated around the core bobbin B. By this rotation, the monofilament M is wound around the core wire S passing through the mandrel 101, and is formed into a wound sprocket by the screw 102.

Further, a bearing (not shown) is provided on the inner circumferential surface of the second drive shaft 25b, and the fixed shaft 25c is inserted into the bearing. Therefore, the fixed shaft 25c is supported by the second drive shaft 25b so that the second drive shaft 25b is rotatable. Further, a mandrel 101 is fixed to the rear end portion of the fixed shaft 25c. Further, a through hole 26 for passing the core wire S toward the mandrel 101 side is formed on the central axis of the fixed shaft 25c.

Further, as shown in FIG. 2, the first drive shaft 25a and the second drive shaft 25b are arranged in a so-called offset manner, that is, the rotation center axis L1 of the first drive shaft 25a and the second drive shaft 25b. The central axes of rotation L2 are parallel to each other and do not intersect in the width direction.

As shown in FIGS. 1 and 2, the bobbin support portion 30 includes a first side plate portion (first portion) 31a rotatably supported by the first drive shaft 25a, and a second side plate portion (second portion) 31b. The second drive shaft 25b is rotatably supported; the connecting plate 32 connects the first side plate portion 31a and the second side plate portion 31b in the front-rear direction; and the bobbin holder 33 supports the core bobbin B. The first side plate portion 31a and the second side plate portion 31b are flat plates that extend in the vertical direction and the horizontal direction.

The first side plate portion 31a includes a bearing (not shown), and a rear end portion of the first drive shaft 25a is inserted into the bearing. Therefore, the first side plate portion 31a is supported by the first drive shaft 25a so that the first drive shaft 25a is rotatable. The second side plate portion 31b is fixed to the front end portion of the fixed shaft 25c. Therefore, the second side plate portion 31b is one of the fixed shafts 25c. It is rotatably supported with respect to the second drive shaft 25b. That is, the second drive shaft 25b rotates around the fixed shaft 25c.

Thereby, when the first drive shaft 25a rotates, the first drive shaft 25a is rotated in the bearing of the first side plate portion 31a by the bearing of the first side plate portion 31a, and when the second drive shaft 25b is rotated, The bearing of the second wall portion 21b rotates the second drive shaft 25b in the bearing of the second wall portion 21b. Further, since the connecting plate 32 is connected to the first drive shaft 25a and the second drive shaft 25b via the first side plate portion 31a and the second side plate portion 31b, the first drive shaft 25a and the second drive shaft 25b are offset and disposed. The first side plate portion 31a, the second side plate portion 31b, and the connecting plate 32 can be prevented from rotating together with the rotation of the first drive shaft 25a and the second drive shaft 25b. In other words, the bobbin support portion 30 can be prevented from rotating in accordance with the rotation of the first drive shaft 25a and the second drive shaft 25b.

The bobbin holder 33 includes a substantially annular substrate portion 34 that serves as a proximal end portion on the side of the first side plate portion 31a, four rods 35 that extend rearward from the substrate portion 34, and an annular bobbin guide The plate 36 is attached to the front end portions of the four rods 35 so as to straddle the respective rods 35, and guides the inner circumferential surface of the core bobbin B. Then, the cylindrical portion of the core bobbin B is fitted to the four rods 35 and the bobbin guide sheets 36, whereby the core bobbin B is supported by the bobbin holder 33. Further, the substrate portion 34 of the bobbin holder 33 is rotatably attached to the left end portion of the first side plate portion 31a via the hinge portion 65 extending in the vertical direction via the central axis of rotation.

As shown in FIG. 1, FIG. 2, and FIG. 3, the hinge portion 65 includes a pair of upper and lower shaft support portions 66 projecting from the left end surface of the first side plate portion 31a, and a rotating portion 67 disposed at the pair of shaft support portions 66. The substrate portion 34 is integrally attached to the bobbin holder 33, and the rotating shaft 68 is rotatably supported by the rotating portion 67 with respect to the pair of upper and lower shaft supporting portions 66.

Further, in the upper and lower pair of shaft support portions 66 and the rotation portion 67, a shaft insertion hole 66a and a shaft insertion hole 67a through which the rotation shaft 68 is inserted are formed in the vertical direction. The rotating shaft 68 is fixed to the rotating portion 67 by screws so that both ends thereof protrude from the rotating portion 67. Further, the rotation shafts 68 protruding from the rotation portion 67 are respectively inserted into the shaft insertion holes 66a of the upper and lower shaft support portions 66, so that the rotation portion 67 is rotatable. Therefore, the rotating shaft 68 is disposed in a direction orthogonal to the longitudinal direction and the width direction of the connecting plate 32, that is, in the vertical direction. Therefore, the bobbin guide plate 36 side of the bobbin holder 33 can be swung to the left side in the width direction around the rotation shaft 68 of the hinge portion 65.

Further, the swing of the bobbin holder 33 can be rotated from the initial position to about 90 degrees, but the swing angle required for the replacement is about 50 degrees. Moreover, the swing angle can also be limited. In this case, the operation can be completed as compared with the case where the work place is rotated by 90 degrees in the swing state, and the swing angle is small. Further, the above-described swing is horizontally rotated, but it is also possible to swing in the upward direction in the vertical direction perpendicular to the horizontal plane. In this case, the core bobbin B is replaced from the upper side of the winding element forming device 100.

As shown in FIGS. 1 and 2, the guide supporting portion 50 for supporting the core wire guiding portion 45 is a substantially annular member, and a fitting convex portion 51 is formed on one surface thereof, and the fitting convex portion 51 is detachably fitted. The inner circumferential surface of the bobbin guide plate 36 of the bobbin holder 33. Therefore, the guide supporting portion 50 including the core wire guiding portion 45 can be detachably attached to the bobbin guiding plate 36 which is the front end portion of the bobbin holder 33.

Further, a core guide portion 45 and a balance portion 46 are attached to the center portion of the guide support portion 50, and the core guide portion 45 extends in a direction perpendicular to the front-rear direction, and the length thereof exceeds the core wire S around the core bobbin. The portion of the diameter in the state of B is bent to the front side and has a substantially L shape, and the balance portion 46 extends symmetrically with the core guide portion 45 around the central axis of the guide support portion 50, and is substantially L. Word shape. Similarly to the core guide portion 45, the balance portion 46 has a flat shape for making the load applied to the central shaft during rotation uniform. In addition, the balance portion 46 may not be required.

Further, the core wire guide portion 45 is formed with a first core wire insertion hole 45a and a second core wire insertion hole 45b through which the core wire S is inserted. In addition, the core wire S wound from the core bobbin B is inserted into the first core wire insertion hole 45a from the outer side of the core wire guide portion 45 toward the core wire guide portion 45, and then pulled out from the core wire guide portion 45 in the backward direction. The outer side is inserted into the second core wire insertion hole 45b toward the core bobbin B side. Further, a guide portion 45c that guides the core wire S that has passed through the first core wire insertion hole 45a and the second core wire insertion hole 45b to the core wire buffer described below is formed in the center portion of the guide support portion 50 ( Buffer) mechanism 80.

Further, in the present embodiment, as shown in FIG. 1, a locking mechanism 75 is provided in the hinge portion 65. As shown in FIGS. 3, 4, and 5, the locking mechanism 75 includes a first engaging hole 76a along the side. The vertical direction is formed in the rotating portion 67 of the hinge portion 65; the two second engaging holes 76b are connectable to the first engaging hole 76a, and are formed in the vertical support portion 66 in the vertical direction; the locking pin 77 is locked. When the mechanism 75 is locked, the upper side is inserted into the first engagement hole 76a and the two second engagement holes 76b; and the pin support portion 78 is protruded forward and provided on the left end surface of the first side plate portion 31a, and the lock pin is attached. 77 can be supported by sliding up and down.

Further, a first pin insertion hole 78a through which the lock pin 77 is inserted is formed in the pin support portion 78 in the vertical direction. Further, a second pin insertion hole 78b through which the lock pin 77 is inserted is formed in the connecting plate 32 in the vertical direction.

Further, a hanging bolt 79 is attached to the left end surface of the first side plate portion 31a so as to protrude in the right direction, and the hanging bolt 79 is locked at the locking mechanism 75. At this time, the lock pin 77 is restricted from sliding downward by hooking the operation piece 77a of the lock pin 77. The operation piece 77a extends perpendicularly to the longitudinal direction of the lock pin 77.

Here, the locking by the lock mechanism 75 means that the lock pin 77 is inserted across the first engagement hole 76a of the rotation portion 67 and the second engagement hole 76b of the upper and lower shaft support portions 66. Thereby, the bobbin holder 33 cannot be swung around the rotation shaft 68 of the hinge part 65. Further, the unlocking state refers to a state in which the operation piece 77a of the lock pin 77 is disengaged from the hook bolt 79 and the lock pin 77 is slid in the downward direction, so that the upper end of the lock pin 77 is rotated from the first engagement hole 76a of the rotary portion 67. It is pulled out and located in the second fastening hole 76b of the lower shaft support portion 66. Thereby, the bobbin holder 33 can be swung around the rotation shaft 68 of the hinge portion 65.

A substantially L-shaped bracket 60 is attached to an inner side surface (rear side surface) of the front side wall 21a of the casing 20, and the bracket 60 extends from the inner side surface to a lower side of the locking pin 77 of the locking mechanism 75. The frame 60 is formed with a third engagement hole 60a in the vertical direction, and the third engagement hole 60a is inserted by the lower side of the lock pin 77 when the lock mechanism 75 is unlocked. Further, when the lock is released, the operation piece 77a abuts against the upper surface of the pin support portion 78, and the slide pin 77 is stopped in the downward direction. In this state, the lower side of the lock pin 77 is inserted into the bracket. The third fastening hole 60a of 60 is engaged with each other. Therefore, the first engagement hole 76a, the second engagement hole 76b, the first pin insertion hole 78a, the second pin insertion hole 78b, and the third engagement hole 60a are in a closed state of the hinge portion 65. When the positions are equal to each other in the vertical direction, the lock pin 77 can be slid up and down and inserted into the first engagement hole 76a, the second engagement hole 76b, the first pin insertion hole 78a, the second pin insertion hole 78b, and the like. And the third fastening hole 60a.

Further, as shown in FIGS. 1 and 7, the bobbin supporting portion 30 is provided with a core buffer mechanism 80, and the core buffer mechanism 80 is empty from the core bobbin B. The core S supplied to the mandrel 101 is accumulated while the driving of the winding element forming device 100 is stopped.

The core buffer mechanism 80 includes a base portion 81 that is provided on a surface of the second side plate portion 31b on the side of the core guide portion 45, and a tension adjustment portion 82 that is attached to the left end surface of the base portion 81 and is adjusted. The tension of the core wire S; the four guide bars 83 are attached to the left end surface of the base portion 81 to guide the core wire S; and the pulley 84 is attached to the end portion of the upper surface of the connecting plate 32 on the side of the first side plate portion 31a. .

When the wound sprocket formed in the tension adjusting portion 82 is discharged from the winding sprocket molding apparatus 100 in accordance with the rotation of the screw 102, the tension is adjusted so that the tension in the discharge direction becomes a predetermined value, and the tension is adjusted by the tension. The portion 82 takes out the core wire S from the core bobbin B. The core wire guiding portion 45 is rotated in the direction opposite to the winding direction of the core wire S around the core bobbin B by stretching the core wire S, whereby the core wire S is separated from the core bobbin B, and the separated core wire S is buffered by the core wire. The mechanism 80 is derived and supplied to the mandrel 101. Therefore, the mechanism for driving is not provided for the rotation of the core guide portion 45.

In the core wire supply device 10 configured as described above, the upper side of the lock pin 77 is inserted into the first engagement hole 76a of the rotary portion 67 of the hinge portion 65 and the upper and lower shaft supports by sliding the lock pin 77 upward. In the second engagement hole 76b of the portion 66, the lock mechanism 75 is in the locked state, and the bobbin holder 33 cannot swing (see Fig. 4). Further, the lower side of the lock pin 77 is inserted into the third engagement hole 60a of the bracket 60 by sliding the lock pin 77 downward, whereby the lock mechanism 75 is released, and the bobbin holder 33 can swing (refer to the figure). 5).

Further, when the lock mechanism 75 is unlocked, when the bobbin holder 33 is swung to the left in the width direction in order to replace the core bobbin B (refer to 6 and 7), gravity acts on the swinging bobbin holder 33, and the bobbin supporting portion 30 is rotated about the first drive shaft 25a and the second drive shaft 25b, but the lower side of the lock pin 77 is used. Since the insertion into the third engagement hole 60a of the bracket 60 is performed, the bobbin support portion 30 is restricted from rotating about the first drive shaft 25a and the second drive shaft 25b. Therefore, the position of the bobbin support portion 30 at the time of replacement can be fixed, so that the replacement work can be easily performed, and the burden on the first drive shaft 25a and the second drive shaft 25b due to the rotation of the bobbin support portion 30 can be avoided. Therefore, the durability of the wound sprocket forming apparatus 100 can be improved.

Further, in the present embodiment, the first drive shaft 25a and the second drive shaft 25b are disposed to be offset in the width direction, and the first side plate portion 31a of the bobbin support portion 30 is rotatably supported by the first drive shaft 25a. The second side plate portion 31b of the bobbin support portion 30 is rotatably supported by the second drive shaft 25b via the fixed shaft 25c, and the first side plate portion 31a and the second side plate portion 31b are coupled by the connecting plate 32, so that the bobbin The support portion 30 and the fixed shaft 25c do not rotate together with the first drive shaft 25a and the second drive shaft 25b.

Hereinafter, the procedure for replacing the core bobbin B in the core wire supply device 10 of the present embodiment will be described with reference to FIGS. 4, 5, 6, and 7.

First, as shown in FIG. 4, when the lock mechanism 75 is locked, that is, the upper side of the lock pin 77 is inserted into the first engagement hole 76a of the rotation portion 67 of the hinge portion 65 and the second of the upper and lower shaft support portions 66. In the state in which the hole 76b is engaged, the bobbin holder 33 cannot be swung to the left side in the width direction.

Next, as shown in FIG. 5, after the operation piece 77a of the lock pin 77 is disengaged from the hook bolt 79, the lock pin 77 is slid downward, whereby the upper side of the lock pin 77 is pulled out from the first engagement hole 76a. And the lower side of the locking pin 77 is inserted into the bracket In the third fastening hole 60a of 60. Thereby, the lock mechanism 75 is in the unlocked state, and the rotation of the bobbin support portion 30 is restricted.

Then, as shown in FIGS. 6 and 7, after the bobbin holder 33 is swung to the left in the width direction, the guide support portion 50 is removed from the bobbin holder 33. Then, the core bobbin B in the state of the coreless wire S is slid in the direction away from the substrate portion 34 along the rod 35, and the core bobbin B is pulled out from the bobbin holder 33. Then, the core bobbin B around which the core wire S is wound is newly inserted into the bobbin holder 33 from the side of the bobbin guide sheet 36 toward the substrate portion 34. Thereafter, after the guide support portion 50 is attached to the bobbin holder 33, the bobbin holder 33 is swung to the right side in the width direction, and the hinge portion 65 is brought into a closed state. Further, at the time of replacement, the state in which the core wire S before the replacement is inserted into the first core wire insertion hole 45a of the core wire guiding portion 45 or the core wire S before the replacement is located in the core wire guiding portion 45 of the tension adjusting portion 82 In the state, it is easier to connect the core wire S of the new core bobbin B to the front core wire S after the replacement, so that the replacement work can be easily performed.

Next, after the lock pin 77 is slid upward, the operation piece 77a of the lock pin 77 is hooked to the sling bolt 79, whereby the upper side of the lock pin 77 is inserted into the first engagement hole 76a, and the lock pin 77 is The lower side is pulled out from the third engagement hole 60a of the bracket 60. Thereby, the lock mechanism 75 is in a locked state, and the replacement work of the core bobbin B is completed.

As described above, according to the core wire supply device 10 of the present embodiment, the base end portion of the bobbin holder 33 of the bobbin support portion 30 is attached to the first drive shaft 25a via the hinge portion 65, and the bobbin holder 33 can The front end portion of the bobbin holder 33 is rotated in the direction away from the second drive shaft 25b around the hinge portion 65. Therefore, the bobbin holder 33 can be swung around the rotation axis of the hinge portion 65. therefore, In a state where the bobbin holder 33 is swung, only the core bobbin B can be inserted and removed with respect to the bobbin holder 33, so that replacement of the core bobbin B can be easily performed. In addition, the replacement time can be shortened, so that the productivity of the wound sprocket can be improved.

Further, according to the core wire supply device 10 of the present embodiment, when the lock mechanism 75 is unlocked, the lower side of the lock pin 77 is inserted into the third engagement hole 60a of the bracket 60 fixed to the casing 20 side, so that the restriction can be restricted. The rotation of the bobbin support portion 30 when the bobbin holder 33 is swung. Therefore, the replacement of the core bobbin B can be performed more easily. Further, since the rotation of the bobbin supporting portion 30 is restricted, the load on the first drive shaft 25a and the second drive shaft 25b due to the rotation of the bobbin support portion 30 can be avoided, so that the winding element forming device can be improved. 100 durability.

Further, according to the core wire supply device 10 of the present embodiment, the guide support portion 50 including the core wire guide portion 45 is attached and detached to the bobbin guide plate 36 at the front end portion of the bobbin holder 33, so that it is not necessary to separately The fixing mechanism is provided so that the manufacturing cost of the winding element forming device 100 can be reduced. Further, since it is not necessary to operate the fixing mechanism, the replacement of the core bobbin B can be performed smoothly.

Further, according to the core wire supply device 10 of the present embodiment, the swing of the bobbin holder 33 is restricted by sliding the lock pin 77 of the lock mechanism 75 upward, and the bobbin support is restricted by sliding the lock pin 77 downward. Since the portion 30 rotates, the one lock pin 77 has two functions. Therefore, it is not necessary to prepare a dedicated mechanism for each function, so that the manufacturing cost of the wound element forming device 100 can be reduced.

The present invention is not limited to the embodiments described in the above embodiments, and may be appropriately modified without departing from the spirit and scope of the invention.

For example, in the present embodiment, the pin supporting portion 78 of the locking pin 77 is provided in the first side plate portion 31a. However, the present invention is not limited thereto, and the pin supporting portion 78 may be provided in the connection. The upper surface of the junction plate 32.

Further, the four rods 35 of the bobbin holder 33 may be one cylindrical member.

10‧‧‧core supply device

20‧‧‧shell

21a, 21b‧‧‧ side wall

25a‧‧‧1st drive shaft

25b‧‧‧2nd drive shaft

25c‧‧‧Fixed shaft

26‧‧‧through holes

30‧‧‧Bob tube support

31a‧‧‧1st side panel (part 1)

31b‧‧‧2nd side panel (part 2)

32‧‧‧Link board

33‧‧‧Bob tube holder

34‧‧‧Parts Department

35‧‧‧ pole

36‧‧‧Bob guide plate

45‧‧‧Guideline for core wire

45a‧‧‧1st core wire insertion hole

45b‧‧‧2nd core wire insertion hole

45c‧‧‧Guidance

46‧‧‧balance department

50‧‧‧guide support

55a‧‧‧1st filament guide

55b‧‧‧2nd filament guide

56‧‧‧ filament insertion hole

57a, 57b‧‧‧balance

60‧‧‧ bracket

60a‧‧‧3rd snap hole

65‧‧‧ Hinge section

66‧‧‧Axis support

67‧‧‧Rotating Department

75‧‧‧Locking mechanism

77‧‧‧Lock pin

78‧‧‧ pin support

79‧‧‧Hanging bolts

80‧‧‧core buffer mechanism

81‧‧‧Base section

82‧‧‧Tensile adjustment department

83‧‧‧ Guide rod

84‧‧‧ pulley

100‧‧‧Rolling sprocket forming device (continuous sprocket forming device for zipper)

101‧‧‧ mandrel

102‧‧‧ screw

B‧‧‧core bobbin

M‧‧‧ monofilament

S‧‧‧ core wire

Claims (6)

A core wire supply device (10) for a continuous chain tooth row forming device (100) for a slide fastener, comprising: a casing (20) having a pair of opposite side walls (21a, 21b); a first drive shaft and a second drive The shafts (25a, 25b) are rotatably supported by the pair of side walls (21a, 21b), respectively; the bobbin support portion (30) is disposed between the first drive shaft and the second drive shaft (25a, 25b) a core bobbin (B) wound with a core wire (S); a core guiding portion (45) that is rotated around the outer circumference of the core bobbin (B) to derive the core wire of the core bobbin (B) And the filament guiding portions (55a, 55b) are respectively disposed on the first driving shaft and the second driving shaft (25a, 25b) to guide the monofilament (M); and the core supplying device is characterized by: The bobbin support portion (30) includes a bobbin holder (33), and a base end portion of the bobbin holder (33) is attached to the first drive shaft (25a) or the second portion via a hinge portion (65) a drive shaft (25b), wherein the bobbin holder (33) can move the front end portion of the bobbin holder (33) away from the first drive shaft or the second drive shaft centering on the hinge portion (65) Direction of (25a, 25b) Turn. The core wire supply device (10) of the continuous chain tooth row forming device (100) for a slide fastener according to the first aspect of the invention, wherein the bobbin support portion (30) includes: a first portion (31a) rotatably The second drive shaft (25b) is rotatably supported by the second drive shaft (25b), and the connecting plate (32) connects the first and second portions (31a) , 31b), and The hinge portion (65) is attached to the first portion or the second portion (31a, 31b). The core wire supply device (10) of the continuous chain dentition forming device (100) according to the second aspect of the invention, wherein the hinge portion (65) includes a rotating portion (67) including a rotating shaft (68) a pair of shaft support portions (66) disposed on both sides of the rotating portion (67) for inserting the rotating shaft (68); and a locking mechanism (75), wherein the locking mechanism (75) includes: a locking hole (76a) is provided in the rotating portion (67); a second engaging hole (76b) is provided in the pair of shaft supporting portions (66); and a locking pin (77) is provided in the locking mechanism (75) When locked, the first engaging hole (76a) and the second engaging hole (76b) are inserted. A core wire feeding device (10) for a continuous chain dentition forming device (100) according to claim 3, wherein the locking mechanism (75) includes a pin supporting portion (78), the pin supporting portion (78) The lock pin (77) is slidably supported in parallel with the rotation shaft (68). A core wire supply device (10) for a continuous chain dentition forming device (100) for a slide fastener according to the third or fourth aspect of the invention, comprising a bracket (60), the bracket (60) being fixed to the shell The body (20) is provided with the side wall (21a) on the side of the hinge portion (65), and extends toward the side wall (21b) facing the side wall (21a), and is formed in the bracket (60). There is a third fastening hole (60a) for locking the locking pin (77) from the first locking mechanism (75) when the locking mechanism (75) is unlocked. Hole (76a) and the above second fastening When the hole (76b) is pulled out and moved, the above-mentioned locking pin (77) is inserted. The core wire supply device (10) of the continuous chain tooth row forming device (100) for a slide fastener according to any one of claims 1 to 5, wherein the front end portion of the bobbin holder (33) A guide supporting portion (50) is detachably provided, and the guide supporting portion (50) rotatably supports the core guiding portion (45).