CN215649567U - Zipper head penetrating and stopping device and zipper assembly all-in-one machine comprising same - Google Patents

Abstract

The utility model discloses a zipper head threading and stopping device and a zipper assembly all-in-one machine comprising the same; the zipper head penetrating and stopping device comprises a clamping and transferring unit, a zipper head penetrating unit and a stopping unit; the stop beating unit can be simultaneously suitable for stop beating processing operation of a forward and reverse penetrating zipper, namely the zipper head penetrating and stop beating device has the advantages of novel structural design, high automation degree, strong adaptability and high flexible manufacturing degree. In addition, the zipper assembly all-in-one machine comprises a zipper conveying device, a continuous zipper tape positioning device, a continuous zipper tape cutting device, a zipper head penetrating device and a stop beating device; the zipper head penetrating and stopping device adopts the zipper head penetrating and stopping device; the zipper assembly all-in-one machine can automatically and efficiently realize the operations of cutting off, threading and stopping the zipper, and can be simultaneously suitable for the processing operation of stopping the zipper of the forward and reverse zipper, and has strong adaptability and high flexible manufacturing degree.

Description

Zipper head penetrating and stopping device and zipper assembly all-in-one machine comprising same

Technical Field

The utility model relates to the technical field of zipper production and processing equipment, in particular to a zipper head penetrating and stopping device and a zipper assembly all-in-one machine comprising the same.

Background

Manufacturing a single slide fastener through a plurality of processes including a cutting process of cutting a continuous semi-finished fastener tape at an upper end portion of a finished slide fastener into a single slide fastener according to a specification length; the zipper is characterized by also comprising a zipper head penetrating process of penetrating a zipper head into the zipper teeth from the upper end part of the zipper; and a stop-up process for forming a stop-up at the upper end of the fastener element.

For a nylon zipper, one surface of the zipper teeth protruding out of the cloth belt is the front surface of the zipper, and the opposite surface of the zipper teeth protruding out of the cloth belt is the back surface of the zipper. After the head penetrating process, the slider penetrates into the zipper teeth, and when the pull piece of the slider is positioned on the front side of the zipper, the head penetrating process is a positive head penetrating process; when the pulling piece of the puller is positioned on the reverse side of the zipper, the head threading procedure is a reverse head threading procedure.

At present, the automation degree and the integration degree of zipper manufacturing equipment are higher and higher, so that a cutting, threading and top stop integrated machine is produced, and the procedures of cutting, threading and top stop can be automatically completed. However, the existing cutting, threading and top stop integrated machine can only meet the top stop procedure of one type of zipper, the integrated machine suitable for the forward threading zipper cannot be suitable for the top stop operation of the reverse threading zipper, and the integrated machine suitable for the reverse threading zipper cannot be suitable for the top stop operation of the forward threading zipper; in the actual zipper production process, in order to meet the requirements of stopping the zipper when the zipper is just penetrated and the zipper is reversely penetrated, two integrated machines are required to be equipped, so that the acquisition cost of a manufacturer is increased.

SUMMERY OF THE UTILITY MODEL

The utility model aims to provide a zipper slider and a stop device, aiming at the defects of the prior art, the zipper slider and the stop device have novel structural design and high automation degree, can be simultaneously suitable for the stop processing operation of a forward and backward penetrating zipper, and have strong adaptability and high flexible manufacturing degree.

Another object of the present invention is to provide a slide fastener assembly machine which can automatically and efficiently perform operations of cutting, threading, and stopping a slide fastener, can be applied to both operations of stopping a slide fastener in a forward and backward direction, and has high adaptability and high flexibility.

In order to achieve the above object, the present invention is achieved by the following technical solutions.

A zipper head penetrating and stopping device comprises a clamping and transferring unit, a zipper head penetrating unit and a stopping unit, wherein the zipper head penetrating unit and the stopping unit are respectively positioned on a walking path of the clamping and transferring unit, and are sequentially arranged at intervals along the walking path of the clamping and transferring unit;

the upper stopping unit comprises a fixed mounting frame, a lifting movable frame and a movable frame driving air cylinder are arranged at the upper end of the fixed mounting frame, the piston rod extending end part of the movable frame driving air cylinder is connected with the lifting movable frame, an ultrasonic transducer which is vertically arranged and electrically connected with an ultrasonic generator is arranged on the lifting movable frame, a welding upper die is arranged at the driving end of the ultrasonic transducer, two upper die forming parts which are right and left opposite and are arranged at intervals are arranged at the lower end part of the welding upper die, and an upper die front side forming groove and an upper die rear side forming groove which are arranged at intervals are respectively formed in the lower surface of each upper die forming part;

the lower end side of the upper welding mould is provided with a front side lower welding mould and a rear side lower welding mould positioned at the rear end side of the front side lower welding mould, and the lifting movable frame is provided with a front side lower mould driving mechanism used for driving the front side lower welding mould to move up and down and a rear side lower mould driving mechanism used for driving the rear side lower welding mould to move up and down; the front side welding lower die is provided with lower die front side forming grooves corresponding to the upper die front side forming grooves respectively, and the rear side welding lower die is provided with lower die rear side forming grooves corresponding to the upper die rear side forming grooves respectively;

the zipper head penetrating and stopping device also comprises two monofilament supply assemblies, wherein one monofilament supply assembly is positioned at the left end side of the upper welding die, and the other monofilament supply assembly is positioned at the right end side of the upper welding die; the fixed mounting frame is provided with a switching driving component, and the two monofilament supply components are respectively arranged at the driving end of the switching driving component.

The front lower die driving mechanism and the rear lower die driving mechanism respectively comprise lower die driving and mounting brackets which are screwed on the lifting movable frame, each lower die driving and mounting bracket is respectively screwed with a lower die driving and lifting cylinder which moves up and down, and the extension end part of a piston rod of each lower die driving and lifting cylinder is respectively provided with a lower die driving and lifting bracket;

the front side welding lower die is arranged at the lower end part of a lower die driving lifting support of the front side lower die driving mechanism, and the rear side welding lower die is arranged at the lower end part of a lower die driving lifting support of the rear side lower die driving mechanism.

The switching driving assembly comprises a switching driving movable frame and a switching driving cylinder which is screwed on the fixed mounting frame and horizontally moves front and back, the extending end part of a piston rod of the switching driving cylinder is connected with the switching driving movable frame, and each monofilament supply assembly is respectively arranged on the switching driving movable frame.

The monofilament supply assembly comprises a monofilament supply mounting frame arranged on the switching driving movable frame, and the monofilament supply mounting frame is provided with a monofilament cutting and pushing mechanism and a monofilament fixed-length transfer mechanism used for supplying the monofilaments to the monofilament cutting and pushing mechanism in a fixed length manner; the zipper head and stop device also comprises a monofilament feeder for continuously supplying the monofilament to the monofilament fixed-length transfer mechanism.

The monofilament cutting and pushing mechanism comprises a movable sliding block, the movable sliding block is provided with a monofilament bin which is opened towards the side of the welding upper die, and the end part of the movable sliding block is provided with a sliding block feeding hole which is communicated with the monofilament bin and used for allowing monofilaments to enter the monofilament bin;

the monofilament supply mounting frame is provided with a cutting driving cylinder which acts along the opening direction of the monofilament storage bin in a threaded manner, the extending end part of a piston rod of the cutting driving cylinder is provided with a cutting driving block, and a movable sliding block is arranged on the cutting driving block;

the monofilament supply mounting frame is provided with a bending forming block positioned at the opening position of the monofilament storage bin of the movable sliding block, and the bending forming block is provided with a bending forming groove which completely penetrates along the opening direction of the monofilament storage bin; when the cutting driving cylinder pushes the cutting driving block and the movable sliding block moves towards the welding upper die side, the movable sliding block and the bending forming block move relatively, and monofilaments entering a monofilament storage bin of the movable sliding block are cut off at a feeding port of the sliding block;

a movable push rod is embedded in a monofilament bin of the movable sliding block, a pushing driving cylinder is screwed in the cutting driving block, a pushing driving block is arranged at the extending end part of a piston rod of the pushing driving cylinder, and the end part of the movable push rod is connected with the pushing driving block; when the pushing driving cylinder pushes the pushing driving block and the movable push rod moves towards the side of the bending forming block, the movable push rod pushes the cut monofilaments into the bending forming grooves of the bending forming block, and in the process, the cut monofilaments pass through the bending forming grooves of the bending forming block and are extruded into a C shape.

The monofilament fixed-length transfer mechanism comprises an upper end fixed guide wire block and a lower end movable guide wire block, wherein the upper end fixed guide wire block and the lower end movable guide wire block are respectively vertically arranged, and the upper end fixed guide wire block is screwed on the monofilament supply mounting frame; a guide wire block driving cylinder which moves up and down is arranged on the filament supply mounting frame corresponding to the movable guide wire block at the lower end, a guide wire block lifting seat is arranged at the extending end part of a piston rod of the guide wire block driving cylinder, and the movable guide wire block at the lower end is arranged at the lower end part of the guide wire block lifting seat;

the upper end fixed wire guide block is provided with an upper end wire guide hole which is completely penetrated up and down and is used for the monofilament to pass through from top to bottom, and the upper end fixed wire guide block is provided with an upper end clearance gap which is provided with a lateral opening and is communicated with the upper end wire guide hole; the monofilament supply mounting frame is hinged with a movable swing rod through a pivot at the side of the fixed guide block at the upper end, one end part of the movable swing rod is provided with a movable pressing wheel which extends into the gap at the upper end, and the other end part of the movable swing rod is provided with a tension spring which causes the movable pressing wheel to press the monofilaments passing through the guide hole at the upper end;

the lower end movable wire guide block is provided with a lower end wire guide hole which is completely penetrated up and down and is used for the monofilament to pass through from top to bottom, and the lower end movable wire guide block is provided with a lower end clearance gap which is provided with a lateral opening and is communicated with the lower end wire guide hole; the wire guide block lifting seat is hinged with a monofilament movable pressure lever by a pivot at the side of the lower end movable wire guide block, and the free end part of the monofilament movable pressure lever is in a wedge shape and extends into a clearance gap at the lower end of the lower end movable wire guide block; the guide wire block lifting seat is provided with a compression spring which pushes the monofilament movable pressing rod upwards at the lower end side of the monofilament movable pressing rod, and the elastic force of the compression spring enables the free end part of the monofilament movable pressing rod to compress the monofilament passing through the guide wire hole at the lower end.

The zipper head penetrating and stopping device further comprises a welding supporting component positioned on the lower end side of the front side welding lower die and the rear side welding lower die.

The welding support assembly comprises a welding support mounting frame, a support block guide seat is arranged at the upper end part of the welding support mounting frame, and a support block guide groove with an upward opening is formed in the support block guide seat;

a front movable bearing block and a rear movable bearing block which are vertically arranged are embedded in a bearing block guide groove of the bearing block guide seat, the front movable bearing block is positioned under the front welding lower die, and the rear movable bearing block is positioned under the rear welding lower die;

a front side bearing driving cylinder which moves up and down is arranged on the welding bearing mounting frame in a threaded manner corresponding to the front side movable bearing block, a front side bearing driving rod is arranged at the extending end part of a piston rod of the front side bearing driving cylinder, and the upper end part of the front side bearing driving rod is connected with the lower end part of the front side movable bearing block;

the welding bearing mounting frame is provided with a rear bearing driving cylinder which moves up and down corresponding to the rear movable bearing block in a threaded manner, a rear bearing driving rod is arranged at the extending end part of a piston rod of the rear bearing driving cylinder, and the upper end part of the rear bearing driving rod is connected with the lower end part of the rear movable bearing block.

The clamping and transferring unit comprises a left side driving linear module and a right side driving linear module, wherein the left side driving linear module and the right side driving linear module synchronously act, the right side driving linear module is positioned on the right side of the left side driving linear module, the left side driving linear module and the right side driving linear module are right opposite to each other and are arranged at intervals, a left side electric cylinder horizontally acts left and right is arranged at the driving end of the left side driving linear module, and a right side electric cylinder horizontally acts left and right is arranged at the driving end of the right side driving linear module; the driving end of the left electric cylinder is provided with a left air clamp, and the driving end of the right electric cylinder is provided with a right air clamp.

A zipper assembly all-in-one machine comprises a zipper conveying device, a continuous zipper tape positioning device, a continuous zipper tape cutting device, a zipper penetrating head and a stop device; the zipper head penetrating and stopping device adopts any one of the zipper head penetrating and stopping devices.

The utility model has the beneficial effects that: the utility model relates to a zipper head penetrating and stopping device which comprises a clamping and transferring unit, a zipper head penetrating unit and a stopping unit, wherein the zipper head penetrating unit and the stopping unit are respectively positioned on a walking path of the clamping and transferring unit, and are sequentially arranged at intervals along the walking path of the clamping and transferring unit; the upper stopping unit comprises a fixed mounting frame, a lifting movable frame and a movable frame driving air cylinder are arranged at the upper end of the fixed mounting frame, the piston rod extending end part of the movable frame driving air cylinder is connected with the lifting movable frame, an ultrasonic transducer which is vertically arranged and electrically connected with an ultrasonic generator is arranged on the lifting movable frame, a welding upper die is arranged at the driving end of the ultrasonic transducer, two upper die forming parts which are right and left opposite and are arranged at intervals are arranged at the lower end part of the welding upper die, and an upper die front side forming groove and an upper die rear side forming groove which are arranged at intervals are respectively formed in the lower surface of each upper die forming part; the lower end side of the upper welding mould is provided with a front side lower welding mould and a rear side lower welding mould positioned at the rear end side of the front side lower welding mould, and the lifting movable frame is provided with a front side lower mould driving mechanism used for driving the front side lower welding mould to move up and down and a rear side lower mould driving mechanism used for driving the rear side lower welding mould to move up and down; the front side welding lower die is provided with lower die front side forming grooves corresponding to the upper die front side forming grooves respectively, and the rear side welding lower die is provided with lower die rear side forming grooves corresponding to the upper die rear side forming grooves respectively; the zipper head penetrating and stopping device also comprises two monofilament supply assemblies, wherein one monofilament supply assembly is positioned at the left end side of the upper welding die, and the other monofilament supply assembly is positioned at the right end side of the upper welding die; the fixed mounting frame is provided with a switching driving component, and the two monofilament supply components are respectively arranged at the driving end of the switching driving component. Through the structural design, the zipper slider and upper stop device can be simultaneously suitable for the upper stop processing operation of a forward and backward zipper, namely the zipper slider and upper stop device has the advantages of novel structural design, high automation degree, strong adaptability and high flexible manufacturing degree.

The utility model has the following beneficial effects: the utility model relates to a zipper assembly all-in-one machine which comprises a zipper conveying device, a continuous zipper tape positioning device, a continuous zipper tape cutting device, a zipper penetrating head and a stop beating device, wherein the continuous zipper tape cutting device is arranged on the continuous zipper tape positioning device; the zipper head penetrating and stopping device adopts any one of the zipper head penetrating and stopping devices. Through the structural design, the integrated zipper assembly machine can automatically and efficiently realize the operations of cutting, threading and stopping the zipper, is simultaneously suitable for the processing operation of stopping the zipper by threading the zipper forwards and backwards, and has strong adaptability and high flexible manufacturing degree.

Drawings

The utility model will be further described with reference to the drawings to which, however, the embodiments shown in the drawings do not constitute any limitation.

Fig. 1 is a schematic structural view of a zipper slider and upper stop device according to the present invention.

Fig. 2 is a schematic structural diagram of the hitting upper stop unit of the present invention.

Fig. 3 is a partial structural schematic diagram of the hitting upper stop unit of the present invention.

FIG. 4 is a schematic view of the filament feeding assembly and the switching driving assembly according to the present invention.

Fig. 5 is a schematic structural view of the monofilament cutting and feeding mechanism and the monofilament fixed-length transfer mechanism of the present invention.

Fig. 6 is a schematic cross-sectional view of the monofilament cutting and pushing mechanism of the present invention.

Fig. 7 is a schematic structural view of an upper stop welding part of the present invention.

Fig. 8 is a schematic structural view of another top dead center welded portion of the present invention.

Fig. 9 is a partial structural view of an upper stop welding portion of the present invention.

Fig. 10 is a schematic structural view of the front side welding lower die and the rear side welding lower die according to the present invention.

Fig. 11 is a schematic structural view of an upper welding die according to the present invention.

Figure 12 is a schematic view of the welded carrier assembly of the present invention.

Figure 13 is a cross-sectional view of the welded support assembly of the present invention.

Fig. 14 is a schematic structural view of the clamping and transferring unit of the present invention.

Fig. 15 is a schematic structural view of the slide fastener assembly machine of the present invention.

Fig. 1 to 15 include:

1-clamping transfer Unit 111-left side drive Linear Module

112-Right side drive Linear Module 121-left side electric Cylinder

122-right side electric cylinder 131-left side air clamp

132-right side air clamp 2-zipper head threading unit

3-upper stop unit 31-fixed mounting bracket

321-lifting movable frame 322-movable frame driving cylinder

323 lifting guide post 324 movable frame guide hole

33 ultrasonic transducer 34 upper welding mould

341 Upper die Molding part 3411 Upper die front side Molding groove

3412 Upper die rear molding groove 351 front side welding lower die

3511-lower die front molding groove 352-rear side welding lower die

3521-lower die rear forming groove 361-front lower die driving mechanism

362-rear lower die driving mechanism 363-lower die driving mounting bracket

364-lower die driving lifting cylinder 365-lower die driving lifting support

37-filament supply group 371-filament supply mounting rack

372-monofilament cutting pushing mechanism 3721-movable sliding block

37211 monofilament bin 37212 slider feed inlet

3722-cutting off driving cylinder 3723-cutting off driving block

3724-bending block 37241-bending groove

3725-movable push rod 3726-push driving cylinder

3727-push driving block 373-monofilament fixed-length transfer mechanism

3731-upper end fixed guide wire block 37311-upper end guide wire hole

37312 upper clearance gap 3732 lower end fixing guide wire block

37321-lower wire guiding hole 37322-lower clearance gap

3733-guide wire block driving cylinder 3734-guide wire block lifting seat

37351 Movable swing link 37352 movable pinch roller

37353 tension spring 37361 monofilament movable pressure lever

37362-compression spring 374-monofilament feeder

38-weld holder assembly 381-weld holder mount

382 supporting block guide seat 3821 supporting block wire guide groove

3831-front movable supporting block 3832-front supporting driving cylinder

3833 front supporting drive rod 3841 rear movable supporting block

3842 rear side bearing drive Cylinder 3843 rear side bearing drive rod

4-switching drive assembly 41-switching drive movable frame

42-switching driving cylinder 43-switching driving guide rail

44-switching driving slide block 5-zipper conveying device

6-continuous zipper tape positioning device 7-continuous zipper tape cutting device.

Detailed Description

The present invention will be described below with reference to specific embodiments.

As shown in fig. 1, a zipper slider and upper stop device comprises a clamping and transferring unit 1, a zipper slider unit 2 and an upper stop unit 3, wherein the zipper slider unit 2 and the upper stop unit 3 are respectively positioned on a traveling path of the clamping and transferring unit 1, and the zipper slider unit 2 and the upper stop unit 3 are sequentially arranged at intervals along the traveling path of the clamping and transferring unit 1.

As shown in fig. 1, 2, 3, 7, 8, 9, and 11, the upper stopping unit 3 includes a fixed mounting frame 31, a lifting movable frame 321 and a movable frame driving cylinder 322 are mounted at the upper end of the fixed mounting frame 31, and the extending end of the piston rod of the movable frame driving cylinder 322 is connected to the lifting movable frame 321; the lifting movable frame 321 is provided with an ultrasonic transducer 33 which is vertically arranged and electrically connected with the ultrasonic generator, and the driving end of the ultrasonic transducer 33 is provided with an upper welding die 34; the lower end of the welding upper die 34 is provided with two upper die forming portions 341 facing right and left and arranged at intervals, and the lower surface of each upper die forming portion 341 is provided with an upper die front forming groove 3411 and an upper die rear forming groove 3412 arranged at intervals in the front-rear direction. It should be explained that, in order to ensure that the lifting movable frame 321 moves up and down stably and reliably under the driving action of the movable frame driving cylinder 322, the present invention adopts the following guiding structure design: the movable frame driving cylinder 322 is screwed on the upper end of the fixed mounting frame 31, the fixed mounting frame 31 is provided with a vertically arranged lifting guide pillar 323, the lifting movable frame 321 is provided with a movable frame guide hole 324 which completely penetrates up and down corresponding to the lifting guide pillar 323, and the lifting guide pillar 323 is embedded in the movable frame guide hole 324 of the lifting movable frame 321.

Further, as shown in fig. 7 to 10, a front welding lower die 351 and a rear welding lower die 352 located at the rear end side of the front welding lower die 351 are installed at the lower end side of the upper welding die 34, and a front lower die driving mechanism 361 for driving the front welding lower die 351 to move up and down and a rear lower die driving mechanism 362 for driving the rear welding lower die 352 to move up and down are installed on the movable lifting frame 321; the front welding lower die 351 has a lower die front molding groove 3511 corresponding to each upper die front molding groove 3411, and the rear welding lower die 352 has a lower die rear molding groove 3521 corresponding to each upper die rear molding groove 3412.

Further, as shown in fig. 1 to 4, the zipper slider and upper stop device further includes two monofilament supply assemblies 37, wherein one monofilament supply assembly 37 is located at the left end side of the upper welding mold 34, and the other monofilament supply assembly 37 is located at the right end side of the upper welding mold 34; the fixed mount 31 is provided with a switching drive unit 4, and two filament feeding units 37 are respectively mounted at the driving ends of the switching drive unit 4.

It is noted that the upper mold front molding groove 3411 and the lower mold front molding groove 3511 of the front welding lower mold 351 constitute a front slide fastener top stop molding position, the upper mold rear molding groove 3412 and the lower mold rear molding groove 3521 of the rear welding lower mold 352 constitute a back slide fastener top stop molding position, that is, the upper mold front molding groove 3411 of the upper mold molding part 341 on the left side and the lower mold front molding groove 3511 on the left side constitute a left upper stopper molding position of the normal slide fastener, the upper mold front molding groove 3411 of the upper mold molding part 341 on the right side and the lower mold front molding groove 3511 on the right side constitute a right upper stopper molding position of the normal slide fastener, the upper mold rear molding groove 3412 of the upper mold molding part 341 on the left side and the lower mold rear molding groove 3521 on the left side constitute a left upper stopper molding position of the reverse slide fastener, and the upper mold rear molding groove 3412 of the upper mold molding part 341 on the right side and the lower mold rear molding groove 3521 on the right side constitute a right upper stopper molding position of the reverse slide fastener. Of course, besides the above arrangement, the following arrangement may be adopted in the present invention: the upper mold front side molding groove 3411 and the lower mold front side molding groove 3511 of the front side welding lower mold 351 form a reverse-penetrating zipper upper stopper molding position, the upper mold rear side molding groove 3412 and the lower mold rear side molding groove 3521 of the rear side welding lower mold 352 form a forward-penetrating zipper upper stopper molding position, that is, the upper mold front side molding groove 3411 of the upper mold molding portion 341 on the left side and the lower mold front side molding groove 3511 on the left side form a left side upper stopper molding position of the reverse-penetrating zipper, the upper mold front side molding groove 3411 of the upper mold molding portion 341 on the right side and the lower mold front side molding groove 3511 on the right side form a right side upper stopper molding position of the reverse-penetrating zipper, the upper mold rear side molding groove 3412 of the upper mold molding portion 341 on the left side and the lower mold rear side molding groove 3521 on the left side form a left side upper stopper molding position of the forward-penetrating zipper, and the upper mold rear side molding groove 3412 of the upper mold molding portion 341 on the right side and the lower mold rear side molding groove 3521 on the right side form a right side molding position of the forward-penetrating zipper.

In the working process of the utility model, the clamping and transferring component clamps the cut zipper to move and enables the zipper to pass through the zipper head penetrating unit 2 and the upper stopping unit 3 in sequence; when the zipper moves to the position of the zipper head penetrating unit 2, the zipper head penetrating unit 2 carries out a head penetrating process and installs the zipper head on the zipper; when the zipper moves to the position of the upper stop unit 3, the upper stop unit 3 performs an upper stop process, and upper stops are formed on the left zipper belt and the right zipper belt of the zipper respectively.

In the process of performing upper stop forming processing by the upper stop unit 3, when the zipper entering the upper stop unit 3 is a front penetrating zipper, the monofilament supply assembly 37 on the left side supplies the monofilament to the upper left stop forming position of the front penetrating zipper, and the monofilament supply assembly 37 on the right side supplies the monofilament to the upper right stop forming position of the front penetrating zipper; when the ultrasonic transducer 33 is started and the upper stop ultrasonic welding molding is carried out, the monofilaments in the left upper stop molding position of the zipper which is being penetrated are welded to the left chain belt of the zipper which is being penetrated, and the monofilaments in the right upper stop molding position of the zipper which is being penetrated are welded to the right chain belt of the zipper which is being penetrated. When the zipper entering the upper stop unit 3 position is a reverse-through zipper, the switching driving mechanism acts and drives the two monofilament supply assemblies 37 to switch and move, so that each monofilament supply assembly 37 is respectively aligned with the corresponding upper stop forming position of the reverse-through zipper, the monofilament supply assembly 37 on the left side supplies the monofilament to the upper left stop forming position of the reverse-through zipper, and the monofilament supply assembly 37 on the right side supplies the monofilament to the upper right stop forming position of the reverse-through zipper; when the ultrasonic transducer 33 is started and the upper stop ultrasonic welding molding is carried out, the monofilaments in the left upper stop molding position of the reverse-through zipper are welded to the left chain belt of the reverse-through zipper, and the monofilaments in the right upper stop molding position of the reverse-through zipper are welded to the right chain belt of the reverse-through zipper.

In the process of the upper stop welding and forming, the movable frame driving cylinder 322 drives the lifting movable frame 321 to move up to the upper limit position, so that the monofilaments of the monofilament supply assembly 37 can be accurately supplied to the upper stop forming position; when the monofilament enters the upper stop forming position, the movable frame driving cylinder 322 drives the lifting movable frame 321 to move down to the lower limit position, so that the zipper can accurately penetrate into the upper stop forming position. When the monofilament enters the upper stop forming station and is subjected to ultrasonic welding, the front welding lower die 351 or the rear welding lower die 352 at the upper stop forming station is closed with the upper welding die 34, and after the upper stop ultrasonic welding is completed, the front lower die driving mechanism 361 or the rear lower die driving mechanism 362 drives the corresponding front welding lower die 351 and the corresponding rear welding lower die 352 to move downwards, so that the zipper formed at the upper stop can be smoothly moved away from the upper stop unit 3 through the clamping and transferring unit 1.

From the above situation, it can be known that, through the above structural design, the zipper slider and the upper stop device of the utility model can be simultaneously applied to the upper stop processing operation of the forward and backward zipper, i.e. the zipper slider and the upper stop device of the utility model have the advantages of novel structural design, high automation degree, strong adaptability and high flexible manufacturing degree.

As shown in fig. 7 to 10, the front lower die driving mechanism 361 and the rear lower die driving mechanism 362 respectively include lower die driving mounting brackets 363 screwed to the movable lifting frame 321, lower die driving lifting cylinders 364 vertically operating are screwed to the lower die driving mounting brackets 363, and lower die driving lifting brackets 365 are respectively mounted to the extended ends of the piston rods of the lower die driving lifting cylinders 364; the front welding lower die 351 is attached to the lower end of the lower die driving elevating bracket 365 of the front lower die driving mechanism 361, and the rear welding lower die 352 is attached to the lower end of the lower die driving elevating bracket 365 of the rear lower die driving mechanism 362.

In the process that the front lower die driving mechanism 361 or the rear lower die driving mechanism 362 drives the corresponding front lower welding die 351 and the corresponding rear lower welding die 352 to move up and down, the lower die drives the lifting cylinder 364 to act and drives the lifting bracket 365 to drive the corresponding front lower welding die 351 and the corresponding rear lower welding die 352 to move up and down through the lower die.

As shown in fig. 1 to 4, the switching drive unit 4 preferably includes a switching drive movable frame 41 and a switching drive cylinder 42 screwed to the fixed mounting frame 31 and horizontally moving forward and backward, an outer end of a piston rod of the switching drive cylinder 42 is connected to the switching drive movable frame 41, and each of the filament supply units 37 is attached to the switching drive movable frame 41. In order to ensure that the switching driving movable frame 41 stably and reliably moves forwards and backwards horizontally, the utility model adopts the following guide structure design: the fixed mounting frame 31 is screwed with a switching driving guide rail 43 horizontally extending along the front-rear direction, the switching driving movable frame 41 is screwed with a switching driving slider 44 corresponding to the switching driving guide rail 43, and the switching driving guide rail 43 is matched with the switching driving slider 44 to form a guide pair structure.

When the upper stop hitting unit 3 switches the upper stop forming station of the front-through zipper and the upper stop forming station of the reverse-through zipper, the switching driving cylinder 42 pushes the switching driving movable frame 41 to move horizontally back and forth, and the switching driving movable frame 41 moving horizontally back and forth drives the two monofilament supply assemblies 37 to synchronously move horizontally back and forth, so that the monofilament supply switching of the upper stop forming station of the front-through zipper and the upper stop forming station of the reverse-through zipper is realized.

Of course, in addition to the switching driving cylinder 42 driving the switching driving movable frame 41 to move horizontally back and forth, the present invention may also drive the switching driving movable frame 41 by means of an electric push rod.

As a preferred embodiment, as shown in fig. 1 to 5, the filament supply unit 37 includes a filament supply mount 371 mounted on the switching drive movable frame 41, the filament supply mount 371 being provided with a filament cutting and pushing mechanism 372, a filament fixed-length transfer mechanism 373 for supplying a single filament fixed length to the filament cutting and pushing mechanism 372; the zipper head threading and stop driving device further includes a monofilament feeder 374 for continuously feeding the monofilament to the monofilament fixed length transfer mechanism 373. During operation, the monofilament feeder 374 continuously feeds out the monofilaments, the monofilaments fed out from the monofilament feeder 374 are transferred to the monofilament cutting and pushing mechanism 372 in a fixed length manner by the monofilament fixed length transfer mechanism 373, and the monofilament cutting and pushing mechanism 372 pushes the cut monofilaments to the molding stop position.

As a preferred embodiment, as shown in fig. 5, the monofilament fixed-length transfer mechanism 373 includes an upper fixed guide block 3731 and a lower movable guide block located at a lower end side of the upper fixed guide block 3731, which are vertically arranged, respectively, and the upper fixed guide block 3731 is screwed to the monofilament supply mount 371; the filament supply mounting frame 371 is provided with a filament guide block driving cylinder 3733 which moves up and down corresponding to the lower movable filament guide block, the extending end part of the piston rod of the filament guide block driving cylinder 3733 is provided with a filament guide block lifting seat 3734, and the lower movable filament guide block is arranged at the lower end part of the filament guide block lifting seat 3734.

The upper end fixed guide wire block 3731 is provided with an upper end guide wire hole 37311 which is completely penetrated up and down and through which a monofilament passes from top to bottom, and the upper end fixed guide wire block 3731 is provided with an upper end clearance notch 37312 which is laterally opened and communicated with the upper end guide wire hole 37311; the monofilament supply mounting rack 371 is hinged with a movable swing link 37351 through a pivot at the side of the upper end fixed thread guide block 3731, one end of the movable swing link 37351 is provided with a movable pressing wheel 37352 extending into the upper end clearance gap 37312, and the other end of the movable swing link 37351 is provided with a tension spring 37353 for promoting the movable pressing wheel 37352 to press the monofilaments passing through the upper end thread guide holes 37311.

Further, the lower end movable guide wire block is provided with a lower end guide wire hole 37321 which completely penetrates up and down and is used for the monofilament to pass through from top to bottom, and the lower end movable guide wire block is provided with a lower end clearance notch 37322 which is laterally opened and communicated with the lower end guide wire hole 37321; the guide wire block lifting seat 3734 is hinged with a monofilament movable pressure lever 37361 through a pivot at the side of the lower movable guide wire block, the free end of the monofilament movable pressure lever 37361 is wedge-shaped and extends into the lower clearance gap 37322 of the lower movable guide wire block; the lower end side of the monofilament movable pressure lever 37361 of the yarn guide block lifting seat 3734 is provided with a compression spring 37362 pushing the monofilament movable pressure lever 37361 upwards, and the elastic force of the compression spring 37362 causes the free end part of the monofilament movable pressure lever 37361 to press the monofilament passing through the lower end yarn guide hole 37321.

In the process of realizing fixed-length transfer of the monofilaments by the monofilament fixed-length transfer mechanism 373, the monofilaments sent out by the monofilament feeder 374 sequentially penetrate into an upper end guide wire hole 37311 of the upper end fixed guide wire block 3731 and a lower end guide wire hole 37321 of the lower end movable guide wire block; when the monofilaments need to be transferred downwards with fixed length, the guide wire block driving cylinder 3733 acts and the guide wire block driving cylinder 3733 pushes the lower end movable guide wire block to move downwards, in the process, the monofilament movable pressing rod 37361 synchronously moves downwards along with the lower end movable guide wire block, the free end part of the monofilament movable pressing rod 37361 presses the monofilaments located in the lower end guide wire hole 37321 under the elastic action of the compression spring 37362, in the process that the monofilament movable pressing rod 37361 synchronously moves downwards along with the guide wire block lifting seat 3734 and the lower end movable guide wire block, the monofilaments are pulled to synchronously move downwards, and the downwards moving distance of the guide wire block lifting seat 3734 is the length of the fixed-length movement of the monofilaments.

It should be noted that, due to the elastic force of the extension spring 37353, the movable pressing wheel 37352 keeps pressing the monofilaments in the upper end yarn guiding hole 37311, and the monofilaments located between the movable pressing wheel 37352 and the monofilament movable pressing rod 37361 can be ensured to be in a tensioned state by the pressing action of the movable pressing wheel 37352 corresponding to the monofilaments, so as to ensure the accuracy of fixed-length transfer.

As a preferred embodiment, as shown in fig. 4 to 6, the monofilament cutting and pushing mechanism 372 includes a movable sliding block 3721, the movable sliding block 3721 is provided with a monofilament storage bin 37211 which is open toward the side of the upper welding die 34, and an end of the movable sliding block 3721 is provided with a sliding block feeding port 37212 which is communicated with the monofilament storage bin 37211 and through which the monofilament enters the monofilament storage bin 37211.

Wherein, the monofilament supply mounting frame 371 is provided with a cutting driving cylinder 3722 moving along the opening direction of the monofilament storage bin 37211 in a threaded manner, the extending end part of a piston rod of the cutting driving cylinder 3722 is provided with a cutting driving block 3723, and the movable sliding block 3721 is arranged on the cutting driving block 3723; the monofilament supply mounting rack 371 is provided with a bending block 3724 positioned at the opening position of the monofilament storage bin 37211 of the movable sliding block 3721, and the bending block 3724 is provided with a bending groove 37241 which completely penetrates along the opening direction of the monofilament storage bin 37211; when the cutting driving cylinder 3722 pushes the cutting driving block 3723 and the movable slider 3721 to move toward the welding upper die 34, the movable slider 3721 and the bending forming block 3724 move relatively to each other, and the monofilament entering the monofilament storage bin 37211 of the movable slider 3721 is cut at the slider feed port 37212.

Further, a movable push rod 3725 is embedded in the monofilament storage bin 37211 of the movable sliding block 3721, a push driving cylinder 3726 is screwed to the cutting driving block 3723, a push driving block 3727 is arranged at the end part of the extension of the piston rod of the push driving cylinder 3726, and the end part of the movable push rod 3725 is connected with the push driving block 3727; when the pushing driving cylinder 3726 pushes the pushing driving block 3727 and the movable push rod 3725 moves toward the bending block 3724, the movable push rod 3725 pushes the cut monofilament into the bending groove 37241 of the bending block 3724, and in the process, the cut monofilament passes through the bending groove 37241 of the bending block 3724 and is extruded into a "C" shape.

During operation, the monofilaments fed by the monofilament fixed-length transfer mechanism 373 with fixed length enter the monofilament storage bin 37211 of the movable sliding block 3721 through the sliding block feed port 37212 of the movable sliding block 3721; after the monofilament fixed-length transfer mechanism 373 finishes the monofilament fixed-length transfer, the cutting driving cylinder 3722 acts, the cutting driving cylinder 3722 pushes the cutting driving block 3723, the movable sliding block 3721 moves towards the welding upper die 34 side, the movable sliding block 3721 and the bending forming block 3724 move relatively, and the monofilament entering the monofilament storage bin 37211 of the movable sliding block 3721 is cut off at the sliding block feed port 37212. The cut monofilament falls into the monofilament storage bin 37211 of the movable sliding block 3721, then the pushing driving cylinder 3726 acts, the pushing driving cylinder 3726 pushes the pushing driving block 3727 and the movable push rod 3725 to move towards the bending forming block 3724, the movable push rod 3725 pushes the cut monofilament into the bending forming groove 37241 of the bending forming block 3724, in the process, the cut monofilament passes through the bending forming groove 37241 of the bending forming block 3724 and is extruded into a "C" shape, and the cut, extruded and bent monofilament is pushed to the molding stop position.

As shown in fig. 1, 12 and 13, the fastener stringer and the upper stop device further include a weld holder 38 positioned at the lower end sides of the front welding lower die 351 and the rear welding lower die 352.

Specifically, the welding support assembly 38 includes a welding support mounting bracket 381, a support block guide seat 382 is installed at an upper end portion of the welding support mounting bracket 381, and a support block guide groove with an upward opening is formed in the support block guide seat 382; a front movable bearing block 3831 and a rear movable bearing block 3841 which are vertically arranged are embedded in a bearing block guide groove of the bearing block guide seat 382, the front movable bearing block 3831 is positioned right below the front welding lower die 351, and the rear movable bearing block 3841 is positioned right below the rear welding lower die 352; a front bearing driving cylinder 3832 which moves up and down is screwed on the welding bearing mounting frame 381 corresponding to the front movable bearing block 3831, a front bearing driving rod 3833 is installed at the end part of the extension of the piston rod of the front bearing driving cylinder 3832, and the upper end part of the front bearing driving rod 3833 is connected with the lower end part of the front movable bearing block 3831; a rear bearing driving cylinder 3842 which moves up and down is screwed to the rear movable bearing block 3841 in the welded bearing mounting bracket 381, a rear bearing driving rod 3843 is mounted at the end of the piston rod extension of the rear bearing driving cylinder 3842, and the upper end of the rear bearing driving rod 3843 is connected to the lower end of the rear movable bearing block 3841.

In the working process of the ultrasonic welding machine, when the front side welding lower die 351 is positioned at the upper stop forming station, the front side bearing driving cylinder 3832 acts and the front side bearing driving cylinder 3832 drives the front side movable bearing block 3831 to move upwards, so that the front side movable bearing block 3831 abuts against the lower surface of the front side welding lower die 351, and during ultrasonic welding machining, the front side movable bearing block 3831 can ensure that the front side welding lower die 351 cannot be displaced, and the stable reliability of ultrasonic welding machining is ensured.

Similarly, when the rear welding lower die 352 is located at the upper stop forming station, the rear bearing driving cylinder 3842 operates and the rear bearing driving cylinder 3842 drives the rear movable bearing block 3841 to move upward, so that the rear movable bearing block 3841 abuts against the lower surface of the rear welding lower die 352, and during ultrasonic welding, the rear movable bearing block 3841 can ensure that the rear welding lower die 352 cannot move, thereby ensuring the stability and reliability of the ultrasonic welding.

As a preferred embodiment, as shown in fig. 14, the clamping and transferring unit 1 includes a left side driving linear module 111 which operates synchronously, and a right side driving linear module 112 which is located at the right end side of the left side driving linear module 111, the left side driving linear module 111 and the right side driving linear module 112 are arranged right and left oppositely and at an interval, a left side electric cylinder 121 which operates horizontally right is installed at the driving end of the left side driving linear module 111, and a right side electric cylinder 122 which operates horizontally right is installed at the driving end of the right side driving linear module 112; the left air clamp 131 is mounted to the driving end of the left electric cylinder 121 and the right air clamp 132 is mounted to the driving end of the right electric cylinder 122.

In the process of clamping and moving the zipper by the clamping and transferring unit 1 of the present invention, the left side driving linear module 111 and the right side driving linear module 112 synchronously operate, the left side driving linear module 111 drives the left side electric cylinder 121 to linearly move, the right side driving linear module 112 drives the right side electric cylinder 122 to linearly move, the left side electric cylinder 121 drives the left side air clamp 131 to move left and right, and the right side electric cylinder 122 drives the right side air clamp 132 to move left and right.

In the process of realizing the linear transfer of the zipper, the left air clamp 131 clamps the left chain belt of the zipper, and the right air clamp 132 clamps the right chain belt of the zipper; when the clamping and transferring unit 1 of the present invention transfers the slide fastener to the position of the slide fastener threading unit 2 and performs the slide fastener threading operation, the left electric cylinder 121 drives the left air clamp 131 to move to the left, and the right electric cylinder 122 drives the right air clamp 132 to move to the right, so that the left and right teeth of the slide fastener are separated from each other, and the left and right teeth of the slide fastener can be smoothly inserted into the slider.

A slide fastener assembling machine, as shown in FIG. 15, comprises a slide fastener conveying device 5, a continuous slide fastener tape positioning device 6, a continuous slide fastener tape cutting device 7, and a slide fastener threading head and a stop-up device; wherein, the zipper head and the upper stop device adopt the zipper head and the upper stop device.

In the integrated machine for assembling zippers, the continuous zippers are fed to the continuous zipper tape positioning device 6 in the conveying and assembling process of the zippers, the continuous zipper tape cutting device 7 cuts the continuous zippers after the continuous zipper tape positioning device 6 positions the continuous zippers, and the cut zippers are subjected to head threading and head stop striking operations through the zipper head threading and head stop striking devices. The zipper conveying device 5, the continuous zipper tape positioning device 6 and the continuous zipper tape cutting device 7 are all conventional designs in the field, and are not described in detail herein.

The above description is only a preferred embodiment of the present invention, and for those skilled in the art, the present invention should not be limited by the description of the present invention, which should be interpreted as a limitation.

Claims (10)

1. A zipper head penetrating and stopping device comprises a clamping and transferring unit (1), a zipper head penetrating unit (2) and a stopping unit (3), wherein the zipper head penetrating unit (2) and the stopping unit (3) are respectively positioned on a walking path of the clamping and transferring unit (1), and the zipper head penetrating unit (2) and the stopping unit (3) are sequentially arranged at intervals along the walking path of the clamping and transferring unit (1);

the method is characterized in that: the upper stopping unit (3) comprises a fixed mounting frame (31), a lifting movable frame (321) and a movable frame driving cylinder (322) are arranged at the upper end of the fixed mounting frame (31), the extending end part of a piston rod of the movable frame driving cylinder (322) is connected with the lifting movable frame (321), an ultrasonic transducer (33) which is vertically arranged and electrically connected with an ultrasonic generator is arranged on the lifting movable frame (321), a welding upper die (34) is arranged at the driving end of the ultrasonic transducer (33), two upper die forming parts (341) which are right and left opposite and are arranged at intervals are arranged at the lower end part of the welding upper die (34), and upper die front side forming grooves (3411) and upper die rear side forming grooves (3412) which are arranged at intervals in the front and at the back are respectively formed in the lower surface of each upper die forming part (341);

a front side welding lower die (351) and a rear side welding lower die (352) positioned at the rear end side of the front side welding lower die (351) are arranged at the lower end side of the welding upper die (34), and a front side lower die driving mechanism (361) for driving the front side welding lower die (351) to move up and down and a rear side lower die driving mechanism (362) for driving the rear side welding lower die (352) to move up and down are arranged on the lifting movable frame (321); the front welding lower die (351) is provided with lower die front forming grooves (3511) corresponding to the upper die front forming grooves (3411), and the rear welding lower die (352) is provided with lower die rear forming grooves (3521) corresponding to the upper die rear forming grooves (3412);

the zipper head penetrating and stopping device also comprises two monofilament supply assemblies (37), wherein one monofilament supply assembly (37) is positioned at the left end side of the upper welding die (34), and the other monofilament supply assembly (37) is positioned at the right end side of the upper welding die (34); the fixed mounting frame (31) is provided with a switching driving component (4), and the two monofilament supply components (37) are respectively arranged at the driving end of the switching driving component (4).

2. A zipper slider and upper stop device according to claim 1, wherein: the front lower die driving mechanism (361) and the rear lower die driving mechanism (362) respectively comprise lower die driving and mounting brackets (363) which are screwed on the lifting movable frame (321), each lower die driving and mounting bracket (363) is respectively screwed with a lower die driving and lifting cylinder (364) which moves up and down, and the extension end part of a piston rod of each lower die driving and lifting cylinder (364) is respectively provided with a lower die driving and lifting bracket (365);

the front welding lower die (351) is mounted at the lower end of a lower die driving lifting bracket (365) of a front lower die driving mechanism (361), and the rear welding lower die (352) is mounted at the lower end of a lower die driving lifting bracket (365) of a rear lower die driving mechanism (362).

3. A zipper slider and upper stop device according to claim 1, wherein: the switching driving assembly (4) comprises a switching driving movable frame (41) and a switching driving cylinder (42) which is screwed on the fixed mounting frame (31) and horizontally moves back and forth, the extending end part of a piston rod of the switching driving cylinder (42) is connected with the switching driving movable frame (41), and each monofilament supply assembly (37) is respectively arranged on the switching driving movable frame (41).

4. A zipper slider and slider assembly as defined in claim 3, wherein: the monofilament supply component (37) comprises a monofilament supply mounting frame (371) arranged on the switching drive movable frame (41), the monofilament supply mounting frame (371) is provided with a monofilament cutting and pushing mechanism (372) and a monofilament fixed-length transfer mechanism (373) for supplying the monofilament fixed-length to the monofilament cutting and pushing mechanism (372); the zipper head threading and stop motion device further comprises a monofilament feeder (374) for continuously feeding the monofilament to the monofilament fixed length transfer mechanism (373).

5. A zipper slider and slider assembly as defined in claim 4, wherein: the monofilament cutting and pushing mechanism (372) comprises a movable sliding block (3721), the movable sliding block (3721) is provided with a monofilament bin (37211) which is opened towards the side of the upper welding die (34), and the end part of the movable sliding block (3721) is provided with a sliding block feeding hole (37212) which is communicated with the monofilament bin (37211) and is used for enabling monofilaments to enter the monofilament bin (37211);

the monofilament supply mounting frame (371) is provided with a cutting driving cylinder (3722) which acts along the opening direction of the monofilament storage bin (37211) in a threaded manner, the extending end part of a piston rod of the cutting driving cylinder (3722) is provided with a cutting driving block (3723), and a movable sliding block (3721) is arranged on the cutting driving block (3723);

the monofilament supply mounting frame (371) is provided with a bending forming block (3724) positioned at the opening position of the monofilament bin (37211) of the movable sliding block (3721), and the bending forming block (3724) is provided with a bending forming groove (37241) which completely penetrates along the opening direction of the monofilament bin (37211); when the cutting driving cylinder (3722) pushes the cutting driving block (3723) and the movable sliding block (3721) moves towards the side of the upper welding die (34), the movable sliding block (3721) and the bending forming block (3724) move relatively, and monofilaments entering a monofilament storage bin (37211) of the movable sliding block (3721) are cut off at a sliding block feeding port (37212);

a movable push rod (3725) is embedded in a monofilament bin (37211) of the movable sliding block (3721), a pushing driving cylinder (3726) is spirally arranged on the cutting driving block (3723), a pushing driving block (3727) is arranged at the extending end part of a piston rod of the pushing driving cylinder (3726), and the end part of the movable push rod (3725) is connected with the pushing driving block (3727); when the pushing driving cylinder (3726) pushes the pushing driving block (3727) and the movable push rod (3725) moves towards the bending forming block (3724), the movable push rod (3725) pushes the cut monofilaments into the bending forming grooves (37241) of the bending forming block (3724), and in the process, the cut monofilaments pass through the bending forming grooves (37241) of the bending forming block (3724) and are extruded into a C shape.

6. A zipper slider and slider assembly as defined in claim 4, wherein: the monofilament fixed-length transfer mechanism (373) comprises an upper end fixed guide wire block (3731) and a lower end movable guide wire block positioned on the lower end side of the upper end fixed guide wire block (3731), wherein the upper end fixed guide wire block (3731) is screwed on the monofilament supply mounting frame (371); the filament supply mounting rack (371) is provided with a filament guide block driving cylinder (3733) which moves up and down corresponding to the movable filament guide block at the lower end, the extending end part of a piston rod of the filament guide block driving cylinder (3733) is provided with a filament guide block lifting seat (3734), and the movable filament guide block at the lower end is arranged at the lower end part of the filament guide block lifting seat (3734);

the upper end fixed guide wire block (3731) is provided with an upper end guide wire hole (37311) which is completely penetrated up and down and through which a monofilament passes from top to bottom, and the upper end fixed guide wire block (3731) is provided with an upper end clearance notch (37312) which is provided with a lateral opening and is communicated with the upper end guide wire hole (37311); a movable swing rod (37351) is hinged at the side of the fixed guide wire block (3731) at the upper end of the monofilament supply mounting frame (371) through a pivot, a movable pressing wheel (37352) extending into the upper end clearance gap (37312) is arranged at one end of the movable swing rod (37351), and a stretching spring (37353) for enabling the movable pressing wheel (37352) to press the monofilaments passing through the upper end guide wire hole (37311) is arranged at the other end of the movable swing rod (37351);

the lower end movable guide wire block is provided with a lower end guide wire hole (37321) which is completely penetrated up and down and through which the monofilament passes from top to bottom, and the lower end movable guide wire block is provided with a lower end clearance gap (37322) which is provided with a lateral opening and is communicated with the lower end guide wire hole (37321); a monofilament movable pressure lever (37361) is hinged to the side of the lower end movable guide wire block by a guide wire block lifting seat (3734) through a pivot, and the free end part of the monofilament movable pressure lever (37361) is wedge-shaped and extends into a lower end clearance gap (37322) of the lower end movable guide wire block; the lower end side of the monofilament movable pressure lever (37361) of the guide wire block lifting seat (3734) is provided with a compression spring (37362) which pushes the monofilament movable pressure lever (37361) upwards, and the elastic force of the compression spring (37362) causes the free end part of the monofilament movable pressure lever (37361) to compress monofilaments passing through the guide wire hole (37321) at the lower end.

7. A zipper slider and upper stop device according to claim 1, wherein: the zipper head penetrating and stopping device also comprises a welding and supporting component (38) which is positioned at the lower end side of the front side welding lower die (351) and the rear side welding lower die (352).

8. A zipper slider and slider assembly as defined in claim 7, wherein: the welding support assembly (38) comprises a welding support mounting frame (381), a support block guide seat (382) is arranged at the upper end part of the welding support mounting frame (381), and a support block guide groove with an upward opening is formed in the support block guide seat (382);

a front movable bearing block (3831) and a rear movable bearing block (3841) which are vertically arranged are embedded in a bearing block guide groove of the bearing block guide seat (382), the front movable bearing block (3831) is positioned right below the front welding lower die (351), and the rear movable bearing block (3841) is positioned right below the rear welding lower die (352);

a front side bearing driving cylinder (3832) which moves up and down is arranged on the welding bearing mounting frame (381) in a threaded mode corresponding to the front side movable bearing block (3831), a front side bearing driving rod (3833) is arranged at the end portion, extending out of a piston rod, of the front side bearing driving cylinder (3832), and the upper end portion of the front side bearing driving rod (3833) is connected with the lower end portion of the front side movable bearing block (3831);

the welding bearing mounting frame (381) is provided with a rear bearing driving cylinder (3842) which moves up and down corresponding to the rear movable bearing block (3841) in a threaded manner, a rear bearing driving rod (3843) is arranged at the end part of the extension of a piston rod of the rear bearing driving cylinder (3842), and the upper end part of the rear bearing driving rod (3843) is connected with the lower end part of the rear movable bearing block (3841).

9. A zipper slider and upper stop device according to claim 1, wherein: the clamping and transferring unit (1) comprises a left side driving linear module (111) which synchronously acts and a right side driving linear module (112) which is positioned at the right end side of the left side driving linear module (111), the left side driving linear module (111) and the right side driving linear module (112) are right-to-left opposite and are arranged at intervals, a left side electric cylinder (121) which horizontally acts left and right is arranged at the driving end of the left side driving linear module (111), and a right side electric cylinder (122) which horizontally acts left and right is arranged at the driving end of the right side driving linear module (112); the driving end of the left electric cylinder (121) is provided with a left air clamp (131), and the driving end of the right electric cylinder (122) is provided with a right air clamp (132).

10. A zipper assembly all-in-one machine comprises a zipper conveying device (5), a continuous zipper tape positioning device (6), a continuous zipper tape cutting device (7), a zipper head penetrating device and a top stop beating device;

the method is characterized in that: the zipper slider and the upper stop device adopt the zipper slider and the upper stop device as claimed in any one of claims 1 to 9.

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