KR101668330B1 - Manufacturing apparatus of pocket type shoes cleaning tissue - Google Patents

Abstract

The bag type shoe sole tissue manufacturing apparatus according to the present invention comprises a supply portion, a joint portion positioned in front of the supply portion, and a cutting portion that cuts a joint portion of the jointed fabric positioned in front of the joint portion and conveyed from the joint portion;
Wherein the feeding part is provided with a superimposing mechanism such that the one-folded fabric unrolled from the roll passes through the superimposition mechanism and folds so as to partially overlap in the width direction and becomes a double-layered fabric having a single-
Wherein the bonding part is provided with a pressing part, and the double-ply fabrics transferred through the supplying part are joined to each other with a bonding part which is pressed by the pressing part and spaced apart in the longitudinal direction and bonded to each other. .

Description

BACKGROUND OF THE INVENTION 1. Field of the Invention [0001] The present invention relates to a bag-

The present invention relates to an apparatus for manufacturing a bag-type shoe sole, and more particularly, to a bag-making apparatus for a bag-type shoe sole, comprising a supply part, a joining part, a perforating part and a cutting part in a series, sequentially from a fabric to a bag- will be.

In general, when a shoe is wiped from a home or an office, a pocket-type shoe-cleaning tissue can be used to easily and efficiently work.

As shown in Figs. 1 and 2, the bag-type shoe-cleaning tissue is formed of a nonwoven fabric material. The pocket type shoe cleaning tissue is fixed by spraying a special shoe wax on the uncoated side (1-1) of the front plate (1) coated with one side. The coated surface (1-2) of the front plate (1) is inwardly directed, and the joined portion (3) is bonded to the back plate (2) not subjected to the coating treatment in a thermal bonding manner. The shoe-making tissue is made in the form of a pocket so that it is possible to work immediately after putting it in the hand through the hand-in mouth (4). The coating surface 1-2 of the front plate 1 prevents the oral wax from penetrating the inside of the tissue and the back plate 2 which is not coated with the coating wipes the dust.

The bag-type shoe-cleaning tissue has a length of the front plate 1 shorter than the length of the back plate 2 so as to make it easier to insert a hand into the shoe-making tissue. On one side of the back plate 2 protruding from the front plate 1, (6) is formed and is easily stored.

However, in the past, a device for manufacturing a bag-type shoe-cleaning tissue has not been developed, and mass production has not been achieved.

Korean Registered Patent No. 20-0205283 (September 22, 2000) Korean Registered Patent No. 10-1525502 (2015.05.28)

SUMMARY OF THE INVENTION The present invention has been proposed in order to solve the above-mentioned problems, and it is an object of the present invention to provide a cutting device, The present invention is directed to a bag-making apparatus for a bag-type shoe sole that can be mass-produced.

The bag type shoe sole tissue manufacturing apparatus according to the present invention comprises a supply portion, a joint portion positioned in front of the supply portion, and a cutting portion that cuts a joint portion of the jointed fabric positioned in front of the joint portion and conveyed from the joint portion;

Wherein the feeding part is provided with a superimposing mechanism such that the one-folded fabric unrolled from the roll passes through the superimposition mechanism and folds so as to partially overlap in the width direction and becomes a double-layered fabric having a single-

Wherein the bonding part is provided with a pressing part, and the double-ply fabrics fed through the feeding part are joined to each other with a bonding part which is pressed by the pressing part to be spaced apart in the longitudinal direction, to provide.

In the above, a hole is further formed between the joining portion and the cutting portion; And a punch is provided in the punching so that holes penetrating the single ply surface are formed between the joining portions of the joining fabric in the punching.

In the above, the supplying portion may further include a roller portion and a first conveying portion;

Wherein the rollers are spaced apart from each other and guide the fabric to be fed to the superimposing mechanism;

Wherein the superimposing mechanism comprises a plate having a slit penetrating in the longitudinal direction and being bent up and down; The bending angle is increased toward the front and the bent portions of the front end portion are arranged side by side so that the end portion of the slit formed on the inner side is communicated and the one side slit is longer than the other side slit and formed parallel to each other;

The first conveying portion includes a first bracket, a plurality of conveying rollers rotatably disposed in parallel with the first bracket, and a first motor installed in the first bracket and driving the conveying roller; And the overlapped two-ply fabric in the superimposing mechanism is fed to the abutment portion through the space between the feed rollers.

In the above, the joining portion comprises a joining device and a second conveying portion spaced forward from the joining device;

The joining device includes a joining portion pedestal extending in the longitudinal direction and having a plurality of first holes penetrating in the vertical direction, a driving shaft having a crank portion extending downward from the joining portion pedestal and extending in the longitudinal direction, and a U- And a lower portion spaced downwardly from the abutment portion and protruding upward through the first hole and spaced apart from each other in the lengthwise direction, a vertically movable portion spaced downwardly from the abutment portion and extending in the longitudinal direction, A connecting part rotatably connected to the up-and-down moving connection shaft at one side and rotatably connected at the other side to the crank part, a connection part connected to the lower part of the upper and lower moving connection part, And an upper copper plate extending in the width direction and having both ends connected to the upper copper plate A second fixing plate having a first hole and a second hole formed therein, a second fixing plate having a second hole formed therein, a pressing part extending vertically and passing through the second hole, a pushing plate disposed at an upper portion thereof and a heat transfer plate disposed at a lower portion thereof, A spring provided between the plates, and an elastic plate provided at the abutment portion and facing the heat transfer plate;

The second conveying portion includes a second conveying portion that is provided in the main body and faces the first conveying roller so as to be spaced apart from each other in the width direction, a third conveying roller that is rotatably installed on the second bracket, A third conveying roller and a driving roller spaced rearwardly in the longitudinal direction, one side of which is eccentrically and rotatably connected to the rotating roller, the other side of which is eccentric to the driving roller, And a plurality of auxiliary rollers rotatably provided on the second bracket and spaced apart from each other around the third conveying roller; And the cloth is passed between the third conveying roller and the auxiliary roller and is supplied to the cutting portion.

In the above, the cutting portion may include a third conveying portion and a cutter;

A second bracket rotatably mounted on the first bracket; a third conveying portion including a plurality of fourth brackets spaced apart from each other in the width direction; a guide shaft rotatably installed on the fourth bracket; a rotation shaft rotatable on the fourth bracket, A roller provided on the rotary shaft spaced apart in the width direction between the brackets, and a motor provided on the fourth bracket for rotatingly driving the rotary shaft; The fabric is passed between the roller and the guide shaft and fed to the cutter;

Wherein the cutter has a plate-like fastening hole formed in a front portion of the fourth bracket and extending in a width direction and having a far-end guide hole penetrating in the longitudinal direction and having a plurality of communication holes at positions spaced from each other at both ends of the far- A moving cutter provided in front of the fixed cutter and provided with moving guide holes spaced apart from both end portions in the width direction and extending upward, a bolt portion which is fastened through the moving guide hole and the communication hole, And a spring provided in the bolt portion to insert the bolt portion into the bolt portion;

The movable cutter is moved in the vertical direction by a cutter power portion provided on the outer side in the width direction of the fourth bracket, and the joint portion of the jointed portion is cut.

The cutter power unit may include a first sprocket provided to rotate integrally with a rotary shaft protruding outwardly from the fourth bracket, a second sprocket coupled with the first sprocket and spaced apart from the first sprocket and rotatably connected to the fourth bracket, Two sprockets and a chain engaging the sprockets; A first transmission shaft having one side eccentrically and rotatably connected to the second sprocket and the other side protruding inward and having a pin slidably inserted in a guide groove of the second transmission shaft; A second transmission shaft rotatably coupled to the third transmission shaft and rotatably mounted on the fourth bracket between the third transmission shaft and the guide groove, And a third transmission shaft rotatably connected to the other end of the second transmission shaft and rotatable on the other side of the movable cutter;

And the cutter power portion is driven so that the movable cutter moves up and down.

The cutting unit may further include a collecting unit; The collecting portion is provided in front of the cutter;

The collecting portion includes a plurality of collecting guide portions extending in the longitudinal direction and spaced apart from each other in the width direction, a second cover rotatably disposed outside the collecting guide portion in the width direction, And a second cover operating portion having one side connected to the second cover and extending outward in the width direction and extending rearward and having an end located below the moving cutter;

When the movable cutter is moved downward, the movable cutter presses down the second cover operating portion to rotate the second cover outward in the width direction, and when the movable cutter is moved upward, it is rotated inward in the width direction so as to be positioned above the collecting guide portion .

In this case, a printing unit is further included between the supplying unit and the bonding unit.

The apparatus for manufacturing a bag-type shoe sole according to the present invention comprises a supply part, a joint part, a perforating part and a cutting part in a series so as to be manufactured from a fabric to a disposable shoe cleaning cloth as a finished product at one time, There is an effect that can be produced.

1 is a front view showing a bag-type shoe-cleaning tissue,
2 is a perspective view showing a use state of the bag-type shoe-cleaning tissue,
FIG. 3 is a schematic diagram illustrating a configuration of a bag-making apparatus for a bag-type shoe cleaning according to the present invention,
FIG. 4 is a plan view showing a supplying part of the bag-making type shoe cleaning machine according to the present invention,
FIG. 5 is a perspective view showing an overlapping mechanism of a supply part of the bag-making type shoe cleaning tissue manufacturing apparatus according to the present invention,
Fig. 6 is a cross-sectional view showing a cross section of part A of the second conveyance part in Fig. 4,
7 is a plan view showing a joint portion of the bag-making type shoe-cleaning tissue manufacturing apparatus according to the present invention,
FIG. 8 is a cross-sectional view showing a section A of FIG. 7,
9 is a front view showing a second transfer part of the joint of the bag type shoe cleaning tissue manufacturing apparatus according to the present invention,
FIG. 10 is a perspective view showing the piercing of the apparatus for manufacturing a bag-type shoe sole according to the present invention,
11 is a perspective view showing a cutting part of the bag-making type shoe-cleaning tissue manufacturing apparatus according to the present invention,
FIG. 12 is a side view illustrating a cutter operation of a cutting portion of a bag-type shoe-making tissue manufacturing apparatus according to the present invention,
FIG. 13 is an exploded perspective view showing a part of a cutting portion of a bag-making type shoe cleaning tissue manufacturing apparatus according to the present invention.

FIG. 3 is a diagram schematically illustrating the configuration of a bag-making apparatus for a bag-type shoe cleaning according to the present invention. FIG. 4 is a plan view showing a supply unit of the apparatus for manufacturing a bag type shoe cleaning according to the present invention, FIG. 6 is a cross-sectional view showing a section A of the second transfer section of FIG. 4, and FIG. 7 is a cross-sectional view of the bag- FIG. 8 is a cross-sectional view taken along the line A of FIG. 7, and FIG. 9 is a cross-sectional view showing a second transferring portion of the joint portion of the bag-type shoe- 10 is a perspective view showing the punching of the bag-making type shoe-cleaning tissue manufacturing apparatus according to the present invention, and Fig. 11 is a perspective view showing a pouch- FIG. 12 is a side view illustrating a cutter operation of a cutting portion of a bag manufacturing apparatus for a bag-like shoe according to the present invention, and FIG. 13 is a perspective view illustrating a cut- Fig. 6 is an exploded perspective view showing a part of a cutting portion of the apparatus. Fig.

4 to 13, the feeding direction of the raw material C is the "longitudinal direction", the direction from the cutter portion 900 to the feeding portion 100 is "rearward", and the cutter portion 900 is cut from the feeding portion 100, Quot; forward ".

3, the bag type shoe cleaning tissue manufacturing apparatus according to the present invention includes a supply unit 100, a printing unit 300, a bonding unit 500, a perforation unit 700, a cutting unit 900 ). Each of the above-described parts may be separately provided in each main body or may be provided in one main body.

As shown in FIGS. 4 to 6, the supply unit 100 is provided at the rear of the bag-type shoe-cleaning tissue manufacturing apparatus according to the present invention. The supply unit 100 is provided at an upper portion of a supply unit body (not shown). The feeding part 100 is composed of two layers of fabric (C2 (double layered fabric) having a double layered surface C 'on one side in the width direction, partially overlapping the folded fabric C (single layered fabric) And moves to the printing unit 300. The supply unit 100 includes a roller unit 110, a stacking mechanism 150, and a first transfer unit 170.

The roller unit 110 includes a plurality of rollers. The roller unit 110 is provided in a bar shape extending in the vertical direction. The roller unit 110 is spaced longitudinally. The roller unit 110 serves to guide the cloth C to be transferred to the superimposing mechanism 150. The roller unit 110 includes a first roller 111, a second roller 133, and a third roller 135.

The first roller 111 is provided with a roll around which a fabric C is wound. The first roller 111 is spaced rearward from the superimposing mechanism 150 and the first conveying unit 170. The first roller 111 is provided to penetrate in a vertical direction on the roll on which the fabric C is wound. The first roller 111 is provided so that a roll on which the fabric C is wound is rotatable.

The second roller 113 is provided between the first roller 111 and the overlapping mechanism 150. The second roller 113 is spaced apart from the first roller 111 and the overlapping mechanism 150. The second roller 113 is provided between the third roller 115 and the first roller 111. The second roller 113 extends vertically. The second roller 113 is rotatably provided.

The third roller 115 is provided between the second roller 113 and the overlapping mechanism 150. The third roller 115 is spaced apart from the second roller 113 and the overlapping mechanism 150. The third roller 115 extends vertically. The third roller 115 is rotatably provided. The second roller 113 and the third roller 115 serve to spread the fabric C unrolled from the first roller 111 in a vertical direction and to be moved to the overlapping mechanism 150.

The superimposition mechanism 150 may be configured such that the second roller 113 and the third roller 115 from the roller unit 110 are arranged such that the angle between the fabric C at the opposite sides of each roller is less than 180 ° . The superimposing mechanism (150) is provided with a quadrilateral plate having slits formed on both sides thereof bent upward and downward. The overlapping mechanism (150) is formed with a slit penetrating in the longitudinal direction. The folded portion of the superimposing mechanism 150 increases in the forward direction and the folded portions are aligned in the front end portion. The single-ply fabric C passes through the slit of the superimposing mechanism 150 and is folded so as to partially overlap in the width direction to form a double-ply fabric C1 having a single-ply surface C 'on one side thereof. The superimposing mechanism 150 includes a guide portion 151 which is a non-bent portion, an upper overlapping portion 153 bent at the upper portion, and a lower overlapping portion 155 bent at the lower portion.

The guide portion 151 is provided so as to have a smaller width in the vertical direction as it goes forward. The guide portion 151 is formed with a slit having a length in the vertical direction and penetrating in the longitudinal direction. The slit is formed in communication with the slit of the upper overlapping portion 153 and the lower overlapping portion 155.

The upper overlapped portion 153 is bent at an upper portion of the guide portion 151. The slit of the upper overlapped portion 153 is provided in communication with the slit of the guide portion 151. The guide portion 151 and the upper overlapping portion 153 are provided so as to increase the bending angle toward the front side. The upper overlapping portion 153 is provided so that the angle between the upper overlapping portion 153 and the guide portion 151 decreases from the rear to the front. The upper overlapped portion 153 is provided so as to have a larger width toward the front.

The lower overlapped portion 155 is provided at a lower portion of the guide portion 151. The slit of the lower overlapped portion 155 is provided in communication with the slit of the guide portion 151. The guide portion 151 and the lower overlapping portion 155 are provided so as to increase the bending angle toward the front side. The lower overlapped portion 155 is provided so that the angle between the lower overlapped portion 155 and the guide portion 151 decreases from the rear to the front. The lower overlapped portion 155 is provided so as to become larger toward the front side.

The lower overlapping portion 155 and the upper overlapping portion 153 are provided in parallel at the front end. The lower overlapping portion 155 and the upper overlapping portion 153 are provided so that the ends of the slit formed at one side in the width direction at the front end portion are in communication with each other. The width of the lower overlapping portion 155 is longer than the upper overlapping portion 153. The width of the upper overlapping portion 153 may be longer than the width of the lower overlapping portion 155.

The first transfer part 170 is spaced apart from the superimposing mechanism 150 in the longitudinal direction. The first transfer unit 170 transfers the double-ply fabric C1 from the superimposing mechanism 150 to the printing unit 300. The first conveying unit 170 discharges the double-ply fabric C1 at a speed at which the printing unit 300 pulls the double-ply fabric C1. The first conveying unit 170 includes a first bracket 171, a conveying roller 173, and a first motor 175.

The first bracket 171 is provided at an upper portion of the supply unit body (not shown). The first bracket 171 is provided in a plate shape. Both ends of the first bracket 171 in the width direction are bent upward.

The conveying roller 173 is disposed between both ends of the first bracket 171 in the width direction. The conveying roller 173 is rotatably installed on the first bracket 171. The conveying roller 173 includes a first conveying roller 1731 and a second conveying roller 1733. The first conveying roller 1731 and the second conveying roller 1733 are arranged in parallel in the vertical direction. The double-ply fabric C1 discharged from the superimposing mechanism 150 passes between the first conveying roller 1731 and the second conveying roller 1733 and is supplied to the printing unit 300.

The first motor 175 is installed in the first bracket 171. The first motor 175 is installed outside one end of the first bracket 171 in the width direction. The first motor 175 drives the conveying roller 173.

The printing unit 300 is positioned in front of the supplying unit 300. The printing unit 300 is a conventional printing apparatus. A figure, a figure, or the like is printed on the double-ply fabric C1 fed from the feeding unit 100 through the printing unit 300. [ The printing unit 300 may be provided between the bonding portion 500 and the perforation 700 or between the perforation 700 and the cutting portion 900. The process of printing by the printing unit 300 is a conventionally known technique, and thus a detailed description thereof will be omitted.

As shown in FIGS. 7 to 9, the joining part 500 is positioned in front of the printing part 300. The joining part 500 is provided on the joining part body 10. The joining portion 500 is formed by joining the double-layered cloth C1 that has been conveyed through the printing portion 300 as a joining cloth C2. The joining fabric C2 has a joining portion which is pressed by the joining portion 500 and is longitudinally spaced and bonded. The overlapped portion of the double-ply fabric C1 of the joining portion is formed by heating and pressing. The joining part 500 includes a joining device and a second conveying part 550.

The joining device is provided on a joining portion pedestal 514 which is an upper portion of the joining portion main body 10. The joining pedestal 514 extends in the longitudinal direction. The joining pedestal 514 has a first hole 514-1 penetrating in the vertical direction. A plurality of the first holes 514-1 are formed. The first holes 514-1 are spaced apart from each other in the width direction and the length direction. The bonding apparatus is composed of a pressing unit 510 and a driving unit 530.

The driving unit 530 is provided at a lower portion of the joining pedestal 514. The driving unit 530 extends in the longitudinal direction. A motor (not shown) is provided at one side of the driving unit 530 and rotated. When the driving unit 530 is rotated by the motor, the pressing unit 510 is driven in the vertical direction. The driving unit 530 includes a driving shaft 531 and a connecting unit 535.

The drive shaft 531 is spaced downwardly from the joint support 514. The drive shaft 531 extends in the longitudinal direction. The drive shaft 531 is formed with a crank portion 533. The crank portion 533 is spaced downwardly from the position where the crimping portion 510 is provided. The crank portion 533 is provided with a connecting portion 535 for connecting the driving shaft 531 and the pressing portion 510.

The connecting portion 535 is spaced downwardly from the joining pedestal 514. The connection portion 535 extends upward. One side of the connecting portion 535 is rotatably connected to the vertically moving connecting shaft 5171 of the pressing portion 510. The other side of the connecting portion 535 is rotatably connected to the crank portion 533. The connection portion 535 is driven in the vertical direction in accordance with the rotation of the drive shaft 531.

The pressing portion 510 is provided through the joining pedestal 514 upwardly. The pressing unit 510 is moved up and down according to the driving of the driving unit 530. The crimping portion 510 is driven in the vertical direction and the double-ply fabrics C1 fed from the printing portion 300 are joined by thermal bonding to form a bonded fabric C2. The pressing portion 510 includes a vertical moving portion 517, an upper copper plate 511, a second fixing plate 513, a pressing portion 5151, and a first fixing plate 512.

The upper and lower moving parts 517 are formed in a "U" shape. The upper and lower moving parts 517 are provided in plural. The upper and lower moving parts 517 are spaced apart from each other in the longitudinal direction. The lower portion of the up-and-down moving part 517 is spaced downward from the abutment pedestal 514. Both ends of the up-and-down moving part 517 protrude up through the first hole 514-1 of the abutment pedestal 514. Both ends of the up-and-down moving part 517 are spaced upward from the abutment pedestal 514. A vertically moving connecting shaft 5171 is provided between the vertically moving upper and lower moving parts 517. The vertically moving connection shaft 5171 is spaced downward from the joining pedestal 514. The vertical movement connecting shaft 5171 extends in the longitudinal direction. Both ends of the vertically moving connection shaft 5171 are connected to the lower portion of the up-and-down moving part 517.

The upper copper plate 511 is provided on the upper portion of the upper and lower movable portions 517. The upper copper plate 511 is spaced upward from the abutment pedestal 514. The upper copper plate 511 is provided in a rectangular plate shape. The upper copper plate 511 has a hole penetrating in the vertical direction. The upper and lower copper plates 511 are connected to ends of the upper and lower movable portions 517 adjacent to each other in the width direction and the longitudinal direction. The upper copper plate 511 is fixedly connected to an upper portion of the upper and lower movable portions 517 by passing through a fixing device such as a bolt in a vertical direction.

The second fixing plate 513 is fixed to the upper portion of the upper copper plate 511. The second fixing plate 513 extends in the width direction. The second fixing plate 513 is spaced inwardly from both longitudinal ends of the upper and lower copper plates 511. Both end portions in the width direction of the second fixing plate 513 are fixed to both ends of the upper and lower copper plates 511 in the width direction. The second fixing plate 513 is formed with a second hole 513-1 penetrating in the vertical direction. The second holes 513-1 are formed in a plurality of spaced apart in the width direction.

The pressing portion 5151 penetrates the second hole 513-1 of the second fixing plate 513. A plurality of the pressing portions 5151 are provided. The pressing portion 5151 extends in the vertical direction. The pressing portions 5151 are spaced apart in the width direction. A pressing plate 515 is fixed to the upper portion of the pressing portion 5151. The pressure plate 515 is provided in a rod shape. The push plate 515 extends in the width direction. The pressing plate 515 is disposed on the upper portion of the second fixing plate 513. A heat transfer plate 5153 is provided below the pressing portion 5151. The heat transfer plate 5153 is made of metal. The heat transfer plate 5153 is provided in the form of a rod. The heat transfer plate 5153 extends in the width direction. A heat ray is provided inside the heat transfer plate 5153. The heat transfer plate 5153 is heated by a built-in hot wire. The pressing portion 5151 is provided through the spring S. The spring S is provided between the second fixing plate 513 and the heat transfer plate 5153. One end of the spring S is disposed in contact with the lower portion of the second fixing plate 513. The other end of the spring S is disposed in contact with the upper portion of the heat transfer plate 5153.

The first fixing plate 512 is fixed to the upper portion of the joining pedestal 514. The first fixing plate 512 is provided in a plate shape. The first fixing plate 512 is provided at a position facing the heat transfer plate 5153. An elastic plate 5121 is fixed to the upper portion of the first fixing plate 512. The elastic plate 5121 is provided at a position facing the heat transfer plate 5153. The elastic plate 5121 is provided in a plate shape. The elastic plate 5121 is formed on the upper portion of the first fixing plate 512 in such a manner that the elastic plate 512 is formed to extend upward in the width direction and spaced apart from the middle portion.

The spring S and the elastic plate 5121 are elastically deformed by the resilient plate 5121 and the heat transfer plate 5121 by elasticity when the double layered cloth C1 positioned between the elastic plate 5121 and the heat transfer plate 5153 is joined. So that the contact time between the plate 5153 and the double-ply fabric C1 becomes long. The contact time C2 between the elastic plate 5121 and the heat transfer plate 5153 and the double-layered cloth C1 is made long so that the bonded fabric C2 having the bonded portion formed by the double-layered cloth C1 is formed .

The second transfer unit 550 is spaced forward from the joining apparatus. The second transferring unit 550 feeds the bonding material C2 formed from the bonding apparatus to the perforating unit 700 while pulling the double layered cloth C1 from the supplying unit 100 or the printing unit 300. [ The second conveyance unit 550 includes a second bracket 11, a third conveyance roller 555, a rotation roller 553, a drive roller 551, a power transmission unit 557, 559).

The second bracket 11 is provided at both end portions in the width direction of the joint body 10 and protrudes forward. The first bracket 11 is formed in a plate shape. The second brackets 11 are spaced apart from each other in the width direction and are provided to face each other.

The third conveying roller 555 is provided between the second brackets 11. The third conveying roller 555 extends in the width direction. The third conveying roller 555 is rotatably disposed about a third conveying roller 555 which is provided through the second bracket 11 in the width direction. The third conveying roller 555 has a protrusion 5551 formed thereon. The protrusions 5551 are formed so as to protrude obliquely along the conveying direction of the joining fabric C2. The protruding portion 5551 has an effect of preventing the joining fabric C2 from moving backward during the reverse rotation.

The rotating roller 553 is positioned outside the second bracket 11. [ The rotating roller 553 is coupled to the end of the rotating shaft of the third feeding roller 555. A clutch release bearing 5531 is coupled between the rotating roller 553 and the second bracket 11. The third transfer roller 555 is rotationally driven in one direction by the clutch release bearing 5531.

The driving roller 551 is spaced longitudinally rearward from the third feeding roller 555. The driving roller 551 is provided on the outside of the joint body 10. The drive roller 551 rotates in the forward direction (direction A). A power transmitting portion 557 is provided between the driving roller 551 and the rotating roller 553.

The power transmitting portion 557 is provided in a rod shape. One side of the power transmitting portion 557 is eccentrically and rotatably connected to the rotating roller 553. The other side of the power transmission portion 557 is eccentric and rotatably connected to the driving roller 551. When the driving roller 551 rotates in accordance with the rotation of the driving roller 551 in the A direction by the power transmission unit 557, the rotation of the driving roller 553 causes the rotation of the rotating roller 553 to be repeated in the B direction.

The auxiliary roller 559 is rotatably provided on the second bracket 11. The plurality of auxiliary rollers 559 are provided. The auxiliary roller 559 is spaced apart from the third conveying roller 555. The joining material C2 discharged from the joining apparatus is pressed between the auxiliary roller 559 and the third conveying roller 555 and is conveyed to the perforation 700 when the third conveying roller 555 is rotated .

Since the rotating roller 553 is coupled to the rotating shaft of the third feeding roller 555 by the clutch bearing 5531 rotating only one way, the third feeding roller 555 rotates only in one direction. When the rotary roller 553 rotates in the B1 direction (forward direction), the third conveying roller 555 rotates integrally with the rotary roller 553 in the B1 direction and conveys the joining fabric C2 forward, and the rotary roller 553 The third conveying roller 555 is not rotated by the clutch bearing 5531 and the third conveying roller 555 is not rotated.

Therefore, the rotation of the drive roller 551 and the rotation of the drive shaft 531 are synchronized with each other by the distance of the conveying distance, and the joint portion is formed. A perforation hole 6 to be described later is formed on the single-ply surface C 'by a distance corresponding to the feed distance, and the cut portion of the cutter portion 900 is cut.

As shown in FIG. 10, the perforation 700 is positioned in front of the joining part 500. The perforation 700 is provided in the perforation body (not shown). The perforation 700 is formed by forming a perforation hole 6 in the single-face surface C 'between the joining portions of the joined fabric C2 that has been transferred through the joining portion 500, ). The perforation hole 6 is formed to pass through in the vertical direction. The perforating unit 700 includes a pedestal 710, a third bracket 750, an induction unit 730, a cylinder 770, and a punch 771.

The pedestal 710 is provided on the upper part of the perforating main body. The pedestal 710 is provided in a plate shape. The pedestal 710 may have a hole penetrating the punch 771 in a vertical direction.

The third bracket 750 is provided at an upper portion of one side in the width direction of the pedestal 710. The third bracket 750 is provided in a plate shape extending upward and extending in a width direction. A portion bent in the width direction of the third bracket 750 is referred to as a protrusion 751. The protrusion 751 extends along the width direction of the pedestal 710. The projecting portion 751 is formed with a hole penetrating the punch 771 in the vertical direction.

The guide portion 730 is provided on the pedestal 710. The guide portion 730 is provided between the protrusion 751 of the third bracket 750 and the pedestal 710. Section of the guide portion 730 is provided in a "C" shape. The guide portion 730 is provided in a plate shape. The guide portion 730 is bent so that both ends of the guide portion 730 face each other in a vertical direction. At both end portions of the guide portion 730, holes are formed in the positions where the punch 771 is provided, the holes being penetrated in the vertical direction.

The cylinder 770 is provided on the protrusion 751 of the third bracket 730. A pressure control inlet pipe 771 and a pressure control outlet pipe 773 are connected to the cylinder 770 to drive a punch 771 provided in the cylinder 770.

The punch 771 is provided below the cylinder 770. The punch 771 extends downward from the cylinder 770. The punch 771 is provided through the hole of the protrusion 751. The lower portion of the punch 771 is spaced upward from the guide portion 730. The lower portion of the punch 771 may be positioned at the upper end of the guide portion 730. When the punch 771 is driven, the hole formed in the guide portion 730 is driven to move up and down.

The single plain surface C 'of the joined fabric C2 supplied to the perforation 700 at the joint portion 500 is moved between the guide portions 730. The punch 771 is driven on the single surface C 'moved between the guide portions 730 to form a perforation hole 6.

11 to 13, the cutting unit 900 is positioned in front of the perforation 700. As shown in FIG. The cutting unit 900 is provided at an upper portion of the cutting unit body 911. The cutting portion 900 cuts the joint portion of the joined fabric C2 transferred from the perforation 700 to complete the bag-type shoe-cleaning tissue. The cutting unit 900 includes a third feeding unit 910, a cutter 930, and a collecting unit 950.

The third feeding unit 910 feeds the cutter 930 with the raw material C3 having the perforation holes 6 transferred from the perforating unit 700. The third feeding part 910 serves to tightly hold the fabric C3 supplied to the cutter 930. The third transfer unit 910 includes a fourth bracket 917, a guide shaft 915, a rotary shaft 913, and a motor.

A plurality of the fourth brackets 917 are provided. The fourth bracket 917 is provided in a plate shape. The fourth bracket 917 is provided at both ends in the width direction of the cutting unit body 911 upward. The fourth brackets 917 are spaced apart from each other in the width direction. A motor is installed outside the one side of the fourth bracket 917 in the width direction. The motor drives the rotary shaft 913 to rotate.

The guide shafts 915 are provided between the fourth brackets 917 spaced in the width direction. The guide shaft 915 extends in the width direction. The guide shaft 915 is rotatably installed on the bracket 917.

The rotation axis 913 is provided between the fourth brackets 917 spaced in the width direction. The rotation axis 913 extends in the width direction. The rotary shaft 913 is spaced upward from the guide shaft 915. The rotation shaft 913 is disposed in parallel to the guide shaft 915. The rotary shaft 913 is rotatably mounted on the fourth bracket 917. The rotary shaft 913 is provided with a roller 9131. The plurality of rollers 9131 are provided. The rollers 9131 are spaced apart from each other in the width direction between the fourth brackets 917.

The far end C3 formed with the perforation hole 6 passes between the roller 9131 and the guide shaft 915 and is supplied to a fabric guide hole 9311 formed in the cutter 930.

The cutter 930 cuts the joining portion of the fabric C3 formed with the perforation holes 6 supplied from the third transfer portion 910 in the width direction. The cutter 930 includes a fixed cutter 931, a movable cutter 933, and a cutter power unit 935.

The fixed cutter 931 is provided in a plate shape. The fixed cutter 931 is fixed to the front of the fourth bracket 917. The fixed cutter 931 is extended in the width direction. The fixed cutter 931 is formed with a far-end guide hole 9311 penetrating in the longitudinal direction. The fabric guide holes 9311 extend in the width direction. A communication hole 9313 is formed in the fixed cutter 931 at positions spaced from each other at both ends of the fabric guide hole 9311 in the width direction. A plurality of the communication holes 9313 are provided. The communication hole 9313 is formed in the longitudinal direction. The communication holes 9313 are spaced apart in the vertical direction.

The movable cutter 933 is provided in a plate shape. The movable cutter 933 is provided in front of the fixed cutter 931. The movable cutter 933 extends in the width direction. At both end portions in the width direction of the movable cutter 933, movement guide holes 9333 are formed. The movement guide hole 9333 is formed to extend upward. A discharge port 9331 is formed between the moving guide holes 9333 of the movable cutter 933. The outlet 9331 is formed to penetrate in the longitudinal direction and open downward. The upper end of the discharge port 9331 is spaced upward from the far end guide hole 9311 of the fixed cutter 931 when the movable cutter 933 moves upward and is spaced downwardly away from the far end guide hole 9311 when moving downward.

The movable cutter 933 and the fixed cutter 931 are fastened by the bolt 937. The bolt portion 937 penetrates through the movement guide hole 9333 of the movable cutter 933 and the communication hole 9313 of the fixed cutter 931 and is fastened. The bolt portion 937 is composed of a bolt 9371, a washer 9375, and a nut 9373. The bolt 9371 penetrates through the spring S and the washer 9373 and is inserted so as to protrude rearward of the fixed cutter 931 in front of the movable cutter 933. [ The spring S is provided between the head of the bolt 9371 and the washer 9375. The nut 9373 is fastened to the bolt 9371 at a rear side of the fixed shoulder 933. The spring S serves to press the movable cutter 933 with the fixed cutter 931.

The cutter power section 935 is provided on the outer side in the width direction of the fourth bracket 917 and is connected to the movable cutter 933. The cutter power section 935 is provided on the outer side in the width direction of the fourth bracket 917 and the cover 919 is provided on the outer side in the width direction of the cutter power section 935. A cover groove 9191 penetrating in the longitudinal direction is formed inside the cover 919 in the width direction. A second transmission shaft 9357 of the cutter power section 935 is extended and protruded in the cover groove 9191. The cutter power section 935 includes a sprocket, a chain 9353, a first transmission shaft 9355, a second transmission shaft 9357, and a third transmission shaft 9359.

The sprocket includes a first sprocket 9351-1 and a second sprocket 9351-2. The first sprocket 9351-1 is provided to rotate integrally with a rotary shaft protruding outwardly from the fourth bracket 917. [ The second sprocket 9351-2 is spaced downwardly from the first sprocket 9351-1. The second sprocket 9351-2 is integrally rotatable with a rotation shaft protruding outwardly from the fourth bracket 917. [ The first sprocket 9351-1 and the second sprocket 9351-2 are connected to the chain 9353. The chain 9351 is engaged with the sprocket and driven. The sprockets and chains may be replaced by pulleys and belts.

The first transmission shaft 9355 extends vertically. One side of the first transmission shaft 9355 is eccentrically connected to the second sprocket 9351-2 so as to be rotatable. The other side of the first transmission shaft 9355 is provided with an inwardly protruding fin. The pin is slidably inserted into the guide groove 9357-1 of the second transmission shaft 9357. [ The first transmission shaft 9355 is slid in the longitudinal direction in the guide groove 9357 by the rotation of the second sprocket 9351-2.

The second transmission shaft 9357 extends in the longitudinal direction. At one side of the second transmission shaft 9357, a guide groove 9357-1 extending in the longitudinal direction thereof is formed. A pin protruding from the first transmission shaft 9355 is slidably inserted into the guide groove 9357-1. The other end of the second transmission shaft 9357 is connected to the third transmission shaft 9359 by a connection shaft 9359-1 so as to be rotatable. The second transmission shaft 9357 is rotatably installed on the fourth bracket 917 between the third transmission shaft 9359 and the guide groove 9357-1. A second transmission rotation shaft 9357-3 is provided in the longitudinal direction of the second transmission shaft 9357. [ The second transmission shaft 9357 is rotated about the second transmission rotation shaft 9357-3.

The third transmission shaft 9359 extends vertically. The lower end of the third transmission shaft 9359 is rotatably connected to the connection shaft 9359-1 at the other end of the second transmission shaft 9357. The upper end of the third transmission shaft 9359 is rotatably connected to the moving cutter 933.

The cutter driving unit 935 is driven by the cutter 930 so that the moving cutter 933 moves up and down to cut the fabric C3 having the perforation holes 6 formed therein.

The collecting unit 950 is disposed in front of the cutter 930. The collecting unit 950 collects and organizes bag-shaped shoe-wiping tissues C4 completed through the cutter 930 with a fabric C3 having a perforation hole 6 formed thereon. The collecting unit 950 includes a collecting guide unit 953, a second cover 955, a hinge 957, and a second cover operating unit 951.

A plurality of the collecting guide portions 953 are provided. The collection guide portion 953 extends in the longitudinal direction. The collecting guide portion 953 is spaced apart in the width direction. A second cover 955 is provided on the upper portion of the collecting guide portion 953. The second cover 955 is connected to the collecting guide portion 953 by a hinge 957 so as to be rotatable outward in the width direction.

The hinge 957 is provided between the collecting guide portion 953 and the second cover 955. One side of the hinge 957 in the up and down direction is fixedly connected to the collecting guide portion 953. The other side of the hinge 957 in the up and down direction is fixedly connected to the second cover 955. The hinge 957 is provided with a coil spring 9571. The second cover 955 is rotated outward in the width direction by the coil spring 9571 and is restored in the upward and downward extension direction of the collecting guide portion 953.

A second cover operating portion 951 is fixedly provided at the rear of the third cover 955 in the longitudinal direction. A plurality of the second cover actuating portions 951 are provided. The second cover operating portion 951 is spaced apart in the width direction. The second cover operating portion 951 extends in the longitudinal direction. One end of the second cover operating portion 951 is connected to the second cover 955, extends outward in the width direction, and extends rearward, and the end portion is positioned below the moving cutter 933.

When the movable cutter 933 is moved downward, the second cover 955 pushes the second cover operating portion 951 downward and is rotated outward in the width direction. When the movable cutter 933 is moved upward And is rotated inward in the width direction so as to be positioned above the collection guide portion 953 when moved.

While the present invention has been particularly shown and described with reference to exemplary embodiments thereof, it will be understood by those skilled in the art that various changes in form and details may be made therein without departing from the spirit and scope of the invention as defined by the appended claims. I will understand. Accordingly, the scope of the true technical protection should be determined by the technical idea of the appended claims.

100: Feeder 110: First roller
130: roller unit 150: overlapping mechanism
170: first transfer unit 300: printing unit
500: bonding portion 510:
530: driving part 550: second conveying part
700: Thinning 710: Pedestal
730: guide part 750: third bracket
770: cylinder 900: cutting portion
910: Third transfer part 930: Cutter
950:

Claims (8)

A joining part 500 positioned in front of the supplying part 100 and a joining part 500 of the joining part 500 positioned in front of the joining part 500 and cutting the joining part of the joining part C2 And a cutting unit (900) for cutting the substrate (100).
The feeding unit 100 is provided with a stacking mechanism 150. The stacking unit 150 folds the stacking unit 150 in a width direction so that the single-ply fabric C unrolled from the roll passes through the stacking mechanism 150, A double-ply fabric (C1) having a double-ply fabric
The joining part 500 is provided with the pressing part 510 and the double folded cloth C1 conveyed through the feeding part 100 is pressed by the pressing part 510 to have a joining part Becomes the joining fabric C2;
The joining part 500 comprises a joining device and a second conveying part 550 spaced forward from the joining device;
The joining device includes a joining portion pedestal 514 extending in the longitudinal direction and formed with a plurality of first holes 514-1 penetrating in the vertical direction and a connecting portion 514 extending downward from the joining portion pedestal 514 in the longitudinal direction, U-shaped ", and the lower part is downwardly spaced from the abutment pedestal 514 and protrudes upward through the first hole 514-1 and is spaced apart in the longitudinal direction A vertically moving connection shaft 5171 which is connected to the lower portion of the vertically movable portion 517 which is spaced apart from the joint support 514 and extends in the longitudinal direction and is spaced apart at both ends, A connecting portion 535 rotatably connected to the vertically moving connection shaft 5171 and rotatably connected to the crank portion 533 at one side thereof and a connecting portion 535 rotatably connected to the crank portion 533 at an upper portion of the elevating moving portion 517, Upwardly spaced A second fixing plate 513 extending in the width direction and provided at both ends of the upper copper plate 511 and having a second hole 513-1 formed thereon, A pressing part 515 penetrating through the first fixing plate 513-1 and having a pressure plate 515 at the upper part and a heat transfer plate 5153 at the lower part and a second fixing plate 513 inserted through the pressing part 5151, A spring S provided between the heat transfer plates 5153 and an elastic plate 5121 provided at a position facing the heat transfer plate 5153 in the joint support 514;
The second conveyance unit 550 includes a second bracket 11 disposed on the main body 10 and spaced apart from and facing the first conveyance unit 550, a third conveyance roller 555 rotatably installed on the second bracket 11, A rotary roller 553 disposed outside the second bracket 11 and coupled to the rotary shaft of the third conveying roller 555 by a clutch release bearing 5531, a third conveying roller 555, A power transmitting portion 557 eccentrically connected to the rotating roller 553 and rotatably connected to the other end of the driving roller 551 and eccentric to the driving roller 551 and rotatably connected to the driving roller 551, And a plurality of auxiliary rollers 559 rotatably provided on the second bracket 11 and spaced along the periphery of the third conveying roller 555; And the fabric is passed between the third conveying roller (555) and the auxiliary roller (559) and supplied to the cutting unit (900). 3. The apparatus of claim 1, further comprising a perforation (700) between the abutment (500) and the cutting portion (900); A punch (771) is provided in the perforation (700), and in the perforation (700), a hole penetrating through the single-faced surface (C ') is formed between the joining portions of the joining fabric (C2) Type shoe-making tissue manufacturing apparatus. The apparatus of claim 1, wherein the supply unit (100) further includes a roller unit (110) and a first transfer unit (170);
The roller unit 110 is spaced apart from the roller unit 110 and guides the fabric C fed to the superimposing unit 150;
The superimposing mechanism (150) is formed in a plate shape having a slit penetrating in the longitudinal direction and bent up and down; The bending angle is increased toward the front and the bent portions of the front end portion are arranged side by side so that the end portion of the slit formed on the inner side is communicated and the one side slit is longer than the other side slit and formed parallel to each other;
The first conveying unit 170 includes a first bracket 171, a plurality of conveying rollers 173 rotatably disposed in parallel with the first bracket 171, And a first motor (175) for driving the roller (173); Wherein the overlapped two-ply fabric (C1) in the overlapping mechanism (150) passes between the conveying rollers (173) and is fed to the joining part (500). delete The cutting apparatus according to claim 1, wherein the cutting unit (900) comprises a third feeding unit (910) and a cutter (930);
The third transfer unit 910 includes a plurality of fourth brackets 917 spaced apart from each other in the width direction, a guide shaft 915 rotatably installed on the fourth bracket 917, A roller 9131 provided on the rotation shaft 913 and spaced apart in the width direction between the fourth bracket 917 and a fourth bracket 917 which is provided in parallel with the guide shaft 915, And a motor for rotationally driving the rotary shaft 913; The raw fabric passes between the roller 9131 and the guide shaft 915 and is supplied to the cutter 930;
The cutter 930 is provided at the front of the fourth bracket 917 and extends in the width direction and has a fabric guide hole 9311 penetrating in the longitudinal direction. The cutter 930 is formed at both ends of the fabric guide hole 9311 in the width direction Shaped fixed cutter 931 in which a plurality of communication holes 9313 are formed at a spaced apart position and a moving guide hole 9333 provided in front of the fixed cutter 931 and spaced apart from both ends in the width direction and extending upward, A bolt portion 937 which penetrates through the movement guide hole 9333 and the communication hole 9313 and a bolt portion 937 which presses the movable cutter 933 with the fixed cutter 931. [ And a spring S inserted in the bolt portion 937;
The moving cutter 933 is moved in the vertical direction by the cutter power section 935 provided on the outer side in the width direction of the fourth bracket 917 and the joined portion of the joined fabric C2 is cut. A shoe-making tissue manufacturing apparatus. The cutter power unit 935 includes a first sprocket 9351-1, a first sprocket 9351-1, a second sprocket 9352-1, and a second sprocket 9352. The first sprocket 9351-1 is rotatable integrally with a rotation shaft protruding outwardly from the fourth bracket 917, A second sprocket 9351-2 connected to the fourth bracket 917 by a chain 9353 and spaced apart from the first sprocket 9351-1 and a chain 9353 meshing with the sprocket 9351 Driven; One end of which is eccentrically and rotatably connected to the second sprocket 9351-2 and the other end of which is inwardly protruded and has a pin slidably inserted into the guide groove 9357-1 of the second transmission shaft 9357 1 transmission shaft 9355 and the guide groove 9357-1 extending in the longitudinal direction is formed at one end and the other end is rotatably coupled to the third transmission shaft 9359 and the third transmission shaft 9359 A second transmission shaft 9357 rotatably installed on the fourth bracket 917 between the guide groove 9357-1 and the guide groove 9357-1 and a second transmission shaft 9357 extending on one side in the vertical direction and extending from the other end of the second transmission shaft 9357 And the other end thereof is composed of a third transmission shaft 9359 rotatably connected to the movable cutter 933;
Wherein the cutter driving unit (935) is driven to move the moving cutter (933) in the vertical direction. The cutting apparatus according to claim 5 or 6, wherein the cutting unit (900) further includes a collecting unit (950); The collecting unit 950 is disposed in front of the cutter 930;
The collecting portion 950 includes a plurality of collecting guide portions 953 extending in the longitudinal direction and spaced apart from each other in the width direction and a second cover (not shown) provided on the upper portion of the collecting guide portion 953 to be rotatable outward in the width direction A hinge 957 provided between the second cover 955 and the collecting guide portion 953 and having a coil scribe 9571 and a hinge 957 having one side connected to the second cover 955, And a second cover operating portion 951 extending outwardly and extending rearward and having an end located below the movable cutter 933;
When the movable cutter 933 is moved downward, the movable cutter 933 presses the second cover operating portion 951 downward so that the second cover 955 is rotated outward in the width direction and the movable cutter 933 is moved upward And is rotated inward in the width direction so as to be positioned above the collecting guide portion (953). The apparatus of claim 2, further comprising a print unit (300) between the supply unit (100) and the joint unit (500).

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