CN111329139A - High-strength oversleeve production machine - Google Patents

Abstract

The high-strength oversleeve production machine is characterized in that two film material rollers are arranged at the end part of the machine table, two sets of film material and rubber band combining devices are arranged on process positions behind the film material rollers, a superposed conveying roller is arranged on the process position behind the film material and rubber band combining devices, a non-woven fabric strip conveying and arranging device is arranged on the process position behind the superposed conveying roller, an ultrasonic welding wheel is arranged on the process position behind the non-woven fabric strip conveying and arranging device, a sealing and cutting part is arranged on the process position behind the ultrasonic welding wheel, and a packing device is arranged on the process position behind the sealing and cutting part.

Description

High-strength oversleeve production machine

Technical Field

The invention relates to manufacturing machinery, in particular to a high-strength oversleeve production machine.

Background

Disposable sleeves are commonly used in daily life, most of the sleeves in the market are finished by sleeve manufacturing machines at present, and after finished sleeves are produced by the existing sleeve manufacturing machines, workers unfold and fold the finished sleeves to be tidily arranged into a certain number of small packages, then transfer the small packages into a middle package, then transfer the small packages into a big package for box sealing, and then put the whole boxes to be tidily arranged. As a result, the production schedule of disposable sleeve products is severely decoupled from the packaging schedule, and many factories have to recruit a large number of workers to perform sleeve packaging. The manual packaging not only reduces the production efficiency, but also can not ensure the quality, and simultaneously improves the production cost of enterprises.

Disclosure of Invention

The invention aims to provide a high-strength oversleeve manufacturing machine, which solves the technical problems that the existing oversleeve manufacturing machine is not reasonable in structure, is disjointed with the production progress of the oversleeve manufacturing machine, is high in production cost, low in production efficiency, difficult to guarantee the product quality and the like.

In order to solve the technical problems, the invention adopts the technical scheme that: a high-strength oversleeve production machine comprises a non-woven fabric strip conveying and arranging device, a machine table, film material rollers and conveying rollers, and is characterized in that two film material rollers are arranged at the end part of the machine table, two sets of film material and rubber band combining devices are arranged at the process positions behind the film material rollers, a superposed conveying roller is arranged at the process position behind the film material and rubber band combining devices, the non-woven fabric strip conveying and arranging device is arranged at the process position behind the superposed conveying roller, an ultrasonic welding wheel is arranged at the process position behind the non-woven fabric strip conveying and arranging device, a sealing and cutting part is arranged at the process position behind the ultrasonic welding wheel, and a packing device is arranged at the process position behind the sealing and cutting part;

the non-woven fabric strip conveying and finishing device comprises a non-woven fabric strip raw material roller and a transmission mechanism, wherein a fabric strip guider is arranged behind the non-woven fabric strip raw material roller, a front transfer wheel is arranged at the rear part of the fabric strip guider, the front transfer wheel is tangent to a press roller, a cutting roller is arranged behind the front transfer wheel and is tangent to a bearing plate, a rear transfer wheel is arranged behind the cutting roller, a fabric strip folding shaper is arranged behind the rear transfer wheel, a slave transfer wheel is arranged behind the fabric strip folding shaper, a straight guide plate is arranged between the rear transfer wheel and the fabric strip folding shaper and penetrates through a winding opening of the fabric strip folding shaper, an arc guide plate is arranged near the outline of the rear transfer wheel, the starting end of the arc guide plate is connected to the bearing surface of the bearing plate, the tail end of the arc guide plate is connected to the straight guide plate, and a section of arc elastic body which can be in close contact with the arc guide plate is fixed at the circumference, and the rear transfer wheel and the driven transfer wheel are wound with transfer belts, and the transfer belts pass through the cloth folding edge shaper and cling to the straight guide plate. .

Preferably, the shaft of the cutting roller is a main transmission shaft, a driving gear is fixed on the shaft, and then the front transmission wheel, the cutting roller and a driven gear on the rear transmission wheel are transmitted through an intermediate gear, and the rear transmission wheel and the driven transmission wheel are transmitted through a transmission belt.

Preferably, the film material and the rubber band combining device are arranged on the machine platform up and down or front and back.

Preferably, the film and rubber band combination device comprises a rubber band positioner, a curling device, curling heat-sealing wheels and a follow-up wheel, wherein the curling heat-sealing wheels are respectively arranged at two sides of the film, the curling device is positioned at the front process position of the curling heat-sealing wheels, and the rubber band positioner is positioned at the front process position of the curling device.

Preferably, a heating ring is wound at the outline of the curling heat-sealing wheel, two poles of an electric heating wire of the heating ring are respectively and electrically connected with annular electrodes sleeved on the curling heat-sealing wheel shaft, and the annular electrodes are respectively connected with carbon brushes.

Preferably, the sealing and cutting part comprises a conveying roller, a sealing and cutting roller and an elastic cutting roller, wherein a bearing and cutting roller is arranged below the sealing and cutting roller and the elastic cutting roller, and an oversleeve conveying belt is arranged in the middle of the elastic cutting roller in a winding manner; the packaging device comprises a feeding roller and a folding device, the folding device is arranged behind the oversleeve conveying belt, a feeding port, a discharging port and an inserting port are arranged on the outer end face of the folding device, the feeding port and the inserting port respectively correspond to the inserting plate, a folding model cavity communicated with the feeding port and the discharging port is arranged in the folding device, the packaging conveying belt is arranged on the side portion or the bottom of the folding device, the feeding port of the folding device is butted with the conveying face of the feeding belt, the discharging port of the folding device is arranged right above the packaging conveying belt, a plurality of clamping grooves for placing the folding oversleeves are formed in the packaging conveying belt, and the clamping grooves are U-shaped; a feeding roller is arranged between the oversleeve conveying belt and the feeding belt, a plurality of groups of material turning forks are radially arranged on the feeding roller, and the material turning forks are crossed with the discharging area on the left side of the feeding belt.

Preferably, the feeding belts are arranged in two groups, and the two groups of feeding belts respectively pass through two sides of the feeding port.

Preferably, one side edge of the packaging conveying belt is provided with a push rod device parallel to the clamping groove, the push rod device is connected with a push rod of the air cylinder, and the other side edge of the packaging conveying belt is provided with a folding sleeve packaging groove corresponding to the push rod device.

Preferably, the push rod device is formed by connecting a plurality of push rods in parallel.

Preferably, a feeding port is formed in the top end of the folding device, and a first vertical model cavity is formed below the feeding port; a second material inserting port is arranged on one side of the first vertical model cavity in the horizontal direction, and a first horizontal model cavity is arranged on the opposite side of the first vertical model cavity in the horizontal direction; a third material inserting port is arranged in the vertical direction of one side of the first horizontal model cavity, and a second vertical model cavity is arranged in the vertical direction of the opposite side of the first horizontal model cavity; a fourth material inserting port is arranged on one side of the second vertical model cavity in the horizontal direction, and a second horizontal model cavity is arranged on the opposite side of the second vertical model cavity in the horizontal direction; a discharge hole is formed in the bottom of the tail end of the second horizontal model cavity, a fifth material inserting hole is correspondingly formed above the discharge hole, a clamping groove is correspondingly formed below the discharge hole, and a first plug board, a third plug board and a fifth plug board are vertically arranged above the material inlet, the third material inserting hole and the fifth material inserting hole respectively; the side edges of the second material inserting port and the fourth material inserting port are respectively and horizontally provided with a second plug board and a fourth plug board; the inserting plates are respectively connected with the push rods of the air cylinders.

Therefore, the full-automatic production line has the advantages of reasonable structure, high efficiency, reliable action, convenient and flexible operation and the like, and is particularly suitable for large-scale full-automatic production of the disposable plastic film sleeves. The produced disposable plastic film oversleeve has reliable quality, is simple and firm, has good waterproof performance and low production cost, and can meet a large amount of requirements of people on the disposable plastic film oversleeve.

Drawings

Fig. 1 is a schematic structural view of the present invention.

Detailed Description

The technical solution of the present invention is further specifically described below by way of examples with reference to the accompanying drawings.

Fig. 1 is a schematic structural view of the present invention. As shown in fig. 1, the high-strength sleeve production machine includes a machine table 25, two film material rollers 1 and 100 for supplying film materials to run are disposed on the machine table 25, all parts of the two film material running lines are disposed on the machine table 25, (of course, the machine table 25 may be one, but is not limited to one), a set of film material and rubber band combining device 8 and 81 is disposed on each of the two film material running lines behind the film material rollers 1 and 100, and the film material and rubber band combining devices 8 and 81 are disposed up and down or back and forth.

The film and rubber band combining device 8 and 81 comprises a rubber band positioner 9, a hemmer 7, a film pressing roller 6, a hemming heat sealing wheel 5 and a follower wheel 4 which are respectively arranged at two sides of the film, wherein the hemmer 7 is positioned at the front part of the hemming heat sealing wheel 5, and the rubber band positioner 9 is positioned at the front part of the hemmer 7.

The curling heat-seal wheel 5 is vertically arranged and contacted with the follow-up wheel 4, the film pressing roller 6 is pressed behind the follow-up wheel 4, the heating ring 3 is wound at the outline of the curling heat-seal wheel 5, two poles of the heating wire of the heating ring 3 are respectively electrically connected with annular electrodes sleeved on the shaft of the curling heat-seal wheel 5, and the annular electrodes are respectively connected with carbon brushes.

The film material running line behind the film material and rubber band combining devices 8 and 81 is provided with a superposition conveying roller 13 for laminating the two film materials. Two sets of non-woven fabric strip conveying and arranging devices 16 used for fixing rubber bands 11 at two ends of a sleeve opening are arranged on a film material running line behind the superposition conveying roller 13, the two sets of non-woven fabric strip conveying and arranging devices 16 are respectively arranged on two sides of the film material 12, an ultrasonic welding wheel 18 is arranged behind the non-woven fabric strip conveying and arranging devices 16, and a sealing and cutting part 22 is arranged behind the ultrasonic welding wheel 18.

The non-woven fabric strip conveying and arranging device 16 comprises a transmission mechanism, a non-woven fabric strip raw material roller 14, a fabric strip guider 82 is arranged behind the non-woven fabric strip raw material roller 14, a guide roller 15 is arranged between the non-woven fabric strip raw material roller and the fabric strip guider 85, the guide roller can rotate or not rotate, a front transfer wheel 83 is arranged at the rear part of the fabric strip guider 82, the front transfer wheel 83 is tangent to a press roller 830 and can pinch the non-woven fabric strip, a cutting roller 85 is arranged behind the front transfer wheel 83, the cutting roller 85 is tangent to a bearing plate 850, a rear transfer wheel 86 is arranged behind the cutting roller 85, a fabric strip folding edge shaper 87 is arranged behind the rear transfer wheel 86, a slave transfer wheel 88 is arranged behind the fabric strip folding edge shaper 87, a straight guide plate 862 is arranged between the rear transfer wheel 88 and the fabric strip folding edge shaper, the straight guide plate 862 passes through a roll opening of the fabric strip folding edge shaper 87, an arc guide plate 860 is arranged near the outline of the rear transfer, the start end of the arc guide plate 860 is connected to the bearing surface of the bearing plate 850, the end of the arc guide plate is connected to the straight guide plate 862, a section of arc elastic body 861 capable of closely contacting the arc guide plate is fixed at the circumference of the surface of the main transfer wheel, the arc elastic body 861 (rubber or elastic plastic, etc.), and in one rotation period of the rear transfer wheel 86, the arc elastic body 861 can scrape a section of non-woven fabric strip 801 at the front end of the arc guide plate 860 into the arc guide plate 860 and make it pass through the arc guide plate 860.

The rear transfer wheel 86 and the driven transfer wheel 88 are wound with a transfer belt 865, and the transfer belt 865 passes through the cloth hem setter 87 and abuts against the straight guide 862.

The transfer wheels 83 and 86 rotate in the same direction, and the cutting roller 85 intermittently cuts the non-woven fabric 82 on the pressure bearing plate 850 by the blade; a slave transfer wheel 88 and a straight guide 862 are provided on both sides of the strip hem sizer 87 for pinching the cut nonwoven strip 82 to the film edge.

In the transmission mechanism, the shaft 805 of the cutter roller 85 is provided as a main transmission shaft, the driving gear 89 is fixed to the shaft 805, and the driven gear on the other shaft is transmitted through the intermediate gear 891, whereby the front transmission wheel, the cutter roller, the rear transmission wheel, and the driven transmission wheel are rotated in the same direction. The rear transmission wheel and the driven transmission wheel are driven by a transmission belt, belong to belt transmission, of course, an intermediate gear can be arranged, and the driven transmission wheel is directly driven by the gear.

The sealing and cutting part 22 mainly comprises a conveying roller 19, a tension adjusting roller 20, a sealing and cutting roller 21 and an elastic cutting roller 23, wherein bearing and cutting rollers 211 and 231 are arranged below the sealing and cutting roller 21 and the elastic cutting roller 23, and the sealing and cutting roller 21 and the elastic cutting roller 23 are driven by gears to synchronously rotate in the same direction. The outer surface of the rubber band cutting roller 23 is wrapped with a rubber sleeve 38, the blade of a rubber band cutter 37 of the rubber band cutting roller 23 is immersed into the surface of the rubber sleeve 38 or is flush with the surface of the rubber sleeve 38, and the middle part of the rubber band cutting roller 23 is wound with a sleeve conveying belt 51.

A feeding roller 521 is arranged between the sleeve conveyor belt 51 and the feeding belt 59, a plurality of groups of material turning forks 522 are radially arranged on the feeding roller 521, and the material turning forks 522 are crossed with a discharging area on the left side of the feeding belt 59. The folding device 53 is externally provided with a feeding port 551 and a discharging port 575, the folding device 53 is internally provided with a folding model cavity communicated with the feeding port 551 and the discharging port 575, and the side part or the bottom part of the folding device 53 is provided with a packing conveyor belt 54.

A first upright model cavity 571 is arranged below a feeding port 551 on the outer end face of the folding device, a second material inserting port 561 is arranged on one side of the first upright model cavity 571 in the horizontal direction, and a first horizontal model cavity 572 is arranged on the opposite side in the horizontal direction; a third material insertion opening 553 is vertically formed at one side of the first horizontal mold cavity 572, and a second vertical mold cavity 573 is vertically formed at the opposite side thereof; a fourth material inlet 563 is horizontally arranged at one side of the second vertical model cavity 573, and a second horizontal model cavity 574 is horizontally arranged at the other side; a discharge port 575 is arranged at the bottom of the tail end of the second horizontal model cavity 574, and a fifth material insertion port 555 is correspondingly arranged above the discharge port 575.

A first inserting plate 552, a third inserting plate 554 and a fifth inserting plate 556 are vertically arranged above the feeding hole 551, the third inserting hole 553 and the fifth inserting hole 555; the side edges of the second material insertion opening 561 and the fourth material insertion opening 563 are provided with a second insertion plate 562 and a fourth insertion plate 564 in parallel, and each insertion plate is connected with the push rod of the cylinder 57.

The feeding ports 551 of the conveying surface folding devices 53 of the feeding belt 9 are butted, the discharging ports 575 of the folding devices 53 are positioned right above the packing conveyor belt 54, a plurality of clamping grooves 541 for placing the folding sleeves are arranged on the packing conveyor belt 54, and the clamping grooves 541 are U-shaped.

The side of the clamping groove 541 is axially provided with a piston push rod device 55, and the push rod device 55 is formed by connecting a plurality of push rods 582 in parallel. A push rod device 55 parallel to the clamping groove 541 is arranged on one side edge of the packing conveyor belt 54, the push rod device 55 is connected with a push rod of the air cylinder, and a folding sleeve packing groove 58 corresponding to the push rod device 55 is arranged on the other side edge of the packing conveyor belt 54.

In operation, the film rolls 1, 100 feed the film 12 into the film and elastic bonding devices 8, 81, respectively. Because the film and rubber band combining devices 8 and 81 have the same structure, the processing process is described by taking the film and rubber band combining device 8 as an example: the film material and rubber band combination device 8 is internally provided with a film material 12 into the hemmer 7, and meanwhile, the rubber band 11 on the rubber band roller 10 is positioned by the rubber band positioner 9 and then immediately enters the hemmer 7, and under the action of the hemmer 7, two sides of the film material 12 are immediately curled and the rubber band 11 is wrapped in the hemmer. After the mold material 12 wrapping the rubber band 11 comes out of the hemmer 7, the film pressing roller 6 arranged at the outlet of the hemmer 7 adjusts the mold material 12, so that the mold material 12 and the rubber band 11 are attached together more tightly. Then, the mold material 12 wrapping the rubber band 11 enters between the follower wheel 4 and the hemming heat-sealing wheel 5 under the driving of the follower wheel 4, the heating ring 3 arranged at the outline of the hemming heat-sealing wheel 5 generates a certain high temperature, the hemming is welded on the film material 12, and the rubber band 11 is sealed in the hemming.

After the film material and rubber band combining devices 8 and 81 combine the film material 12 and the rubber band 11, the film material 12 which is conveyed out by the two devices and is coiled with the rubber band 11 is simultaneously conveyed to the superposition conveying roller 13, and the contra-rotating superposition conveying roller 13 carries out superposition arrangement on the two film materials 12 and then conveys the two film materials into the process position of the non-woven fabric strip conveying and arranging device 16.

In the nonwoven fabric strip transporting and arranging device 16, the nonwoven fabric strip 800 on the nonwoven fabric strip raw material roller 80 is fed between the front transfer wheel 83 and the press roller 830 thereof through the strip guide 82, and the film material 12 subjected to the superposing and arranging is also conveyed near the strip guide 82 on the main conveying line and moves synchronously with the nonwoven fabric strip in one direction.

The non-woven fabric strip 800 is moved, the cutting edge of the cutting roller 85 cuts the non-woven fabric strip 800 on the bearing plate 850 to form a non-woven fabric strip section 801, then the rear transfer wheel 86 is matched with the arc-shaped guide plate, the cut non-woven fabric strip section 801 is clamped, is further pressed by the transfer belt and is conveyed between the transfer wheel 88 and the straight guide plate 862 under the action of the transfer belt, the non-woven fabric strip section 801 is continuously clamped and conveyed by the transfer wheel 88, the transfer belt and the straight guide plate 862 in a matching way and passes through the fabric strip folding shaper 87, at the moment, the front big end and the rear small end of the fabric strip folding shaper 87 are designed to enable the non-woven fabric strip section 801 to be folded in half, the folded non-woven fabric strip section 801 is wrapped on the edges of the two layers of membranes 12, and the non-woven fabric strip section 801 enters the non-woven fabric welding wheel 9 to be welded with the membranes along.

The cloth strip folding shaper is a conventional component of the existing shoe cover making machine, and the structure of the cloth strip folding shaper is as follows: one side of the interior of the cloth strip folding shaper, which is close to the plastic film, is provided with a passage (namely a winding opening), the winding opening has a large inlet and a narrow outlet, and a section of non-woven cloth strip section 801 passing through the winding opening can be folded to wrap the rubber band edge of the film material.

The ultrasonic welding wheel 18 immediately welds the rubber band 11 at the wrapping position of the non-woven fabric strip 141 firmly on the membrane material 12 to form a rubber band fixing area 39. The film material 12 with the nonwoven fabric strips 141 welded thereto is then fed to the processing station of the seal-cutting section 22. When the non-woven fabric strip 141 of the film material 12 runs under the sealing and cutting roller 21, the heat sealing knife on the sealing and cutting roller 21 immediately heat seals and cuts the film material 12 at the middle position of the elastic band fixing area 39 to form the sealing and cutting edge 40 of the sleeve 24. At the moment, the rubber band cutting roller 23 and the cutting bearing rod 231 below the rubber band cutting roller continue to pinch the rubber band 11, when the rubber band pressing rod presses the middle point of the rubber band fixing area 39, the rubber band pressing rod is compressed and contracted at the moment, the blade edge of the rubber band cutter 37 at the position is exposed out of the surface of the rubber sleeve 38 along the trend, and then the rubber band 11 is cut off and finally thrown out to form the finished product sleeve 24. The finished sleeves 24 are transferred by the upender forks 522 to the feed belt 59 by the sleeve conveyor 51, and the feed belt 59 starts to operate when a certain number of finished sleeves 24 are superimposed.

When the finished sleeve 24 passes through the square material inlet 51 on the top panel of the folding device 53, the first inserting plate 552 is inserted into the first vertical mold cavity 571 from the center of the finished sleeve 24; the finished sleeve 24 is press-folded within the U-shaped first upright mold cavity 571. A second material inserting opening 561 is arranged at the center of the side of the first vertical model cavity 571, a first horizontal model cavity 572 is arranged at the other side of the first vertical model cavity 571, and the finished product sleeve 24 is horizontally inserted into the first horizontal model cavity 572 through the second material inserting opening 561 by the second material inserting opening 562, so that the secondary folding of the finished product sleeve 24 is completed.

A third insertion hole 553 is provided above the first horizontal mold cavity 572, a second erected mold cavity 573 is provided below the third insertion hole 553, and the second folded sleeve is inserted into the second erected mold cavity 573 by the third insertion hole 554. A fourth gate 563 is provided at a side of the second upright model cavity 573 and a second horizontal model cavity 574 is provided at an opposite side thereof, and a fourth gate 564 is transversely inserted into the fourth gate 563 to insert a sleeve folded four times into the second horizontal model cavity 574. A discharge port 575 is formed in the bottom of the tail end of the second horizontal model cavity 574, and when the center of the U-shaped clamping groove 541 passes through the center of the fifth insertion port 555, the fifth insertion plate 556 brings the sleeve into the U-shaped clamping groove 541 through the fifth insertion port 555 for fifth folding and final sizing; the folding sleeve packaging groove 58 is internally provided with a packaging bag, and finally the folded and shaped finished sleeve 24 is axially pushed into the packaging bag of the folding sleeve packaging groove 58 by the push rod 582 of the push rod device 55.

Although embodiments of the present invention have been shown and described, it will be appreciated by those skilled in the art that changes, modifications, substitutions and alterations can be made in these embodiments without departing from the principles and spirit of the invention, the scope of which is defined in the appended claims and their equivalents.

Claims (2)

1. A high-strength oversleeve production machine comprises a non-woven fabric strip conveying and arranging device, a machine table, film material rollers and conveying rollers, and is characterized in that two film material rollers are arranged at the end part of the machine table, two sets of film material and rubber band combining devices are arranged at the process positions behind the film material rollers, a superposed conveying roller is arranged at the process position behind the film material and rubber band combining devices, the non-woven fabric strip conveying and arranging device is arranged at the process position behind the superposed conveying roller, an ultrasonic welding wheel is arranged at the process position behind the non-woven fabric strip conveying and arranging device, a sealing and cutting part is arranged at the process position behind the ultrasonic welding wheel, and a packing device is arranged at the process position behind the sealing and cutting part; the non-woven fabric strip conveying and finishing device comprises a non-woven fabric strip raw material roller and a transmission mechanism, wherein a fabric strip guider is arranged behind the non-woven fabric strip raw material roller, a front transfer wheel is arranged at the rear part of the fabric strip guider, the front transfer wheel is tangent to a press roller, a cutting roller is arranged behind the front transfer wheel and is tangent to a bearing plate, a rear transfer wheel is arranged behind the cutting roller, a fabric strip folding shaper is arranged behind the rear transfer wheel, a slave transfer wheel is arranged behind the fabric strip folding shaper, a straight guide plate is arranged between the rear transfer wheel and the fabric strip folding shaper and penetrates through a winding opening of the fabric strip folding shaper, an arc guide plate is arranged near the outline of the rear transfer wheel, the starting end of the arc guide plate is connected to the bearing surface of the bearing plate, the tail end of the arc guide plate is connected to the straight guide plate, and a section of arc elastic body which can be in close contact with the arc guide plate is fixed at the circumference, the rear transfer wheel and the driven transfer wheel are wound with transfer belts, and the transfer belts pass through the cloth strip folding edge shaper and cling to the straight guide plate; the shaft of the cutting roller is a main transmission shaft, a driving gear is fixed on the shaft of the cutting roller, then the front transmission wheel, the cutting roller and the driven gear on the rear transmission wheel are transmitted through the middle gear, and the rear transmission wheel and the driven transmission wheel are transmitted through the transmission belt.

2. The high strength sleeve producing machine as claimed in claim 1, wherein the film and rubber band combining device includes a rubber band positioner, a curling device, a curling heat-sealing wheel and a follower wheel respectively disposed at two sides of the film, the curling heat-sealing wheel and the follower wheel are disposed up and down and in contact, the curling device is located at a front process position of the curling heat-sealing wheel, and the rubber band positioner is located at a front process position of the curling device.

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