CN116078602A

CN116078602A - Fabric coating device and coating method based on radial extrusion opposite feeding

Info

Publication number: CN116078602A
Application number: CN202310379242.5A
Authority: CN
Inventors: 吴海民
Original assignee: Shantou City Tonghui Industry Co ltd
Current assignee: Shantou City Tonghui Industry Co ltd
Priority date: 2023-04-11
Filing date: 2023-04-11
Publication date: 2023-05-09
Anticipated expiration: 2043-04-11
Also published as: CN116078602B

Abstract

The invention discloses a fabric coating device and a coating method based on radial extrusion opposite feeding, and relates to the technical field of fabrics; wherein the coating device includes: the coating pond is symmetrically provided with two groups, a first L-shaped plate and a second L-shaped plate are arranged on the coating pond, and the first L-shaped plate and the second L-shaped plate are symmetrically arranged. This kind of surface fabric coating device based on radial extrusion subtend pay-off through pushing away the cooperation of subassembly, adjusting part, drive assembly, stirring subassembly and coating subassembly, when the surface fabric need carry with faster speed, improves the efficiency of coating, increases the surface fabric and the area of contact on coating roller surface in the transportation process, makes the coating roller in carrying out high-speed rotation in-process, still can guarantee the surface fabric and the abundant counterbalance contact on coating roller surface, the high quality coating processing of surface fabric of being convenient for.

Description

Fabric coating device and coating method based on radial extrusion opposite feeding

Technical Field

The invention relates to the technical field of fabric processing, in particular to a fabric coating device and a fabric coating method based on radial extrusion opposite feeding.

Background

The fabric is the material used for making clothing. As one of the three elements of the garment, the fabric can not only explain the style and the characteristics of the garment, but also directly control the color and the modeling of the garment. The composite coating fabric is a fabric treated by a special process, and can form a layer of uniform covering sizing material on the surface of the fabric so as to achieve the functions of water resistance, wind resistance and the like.

In the prior art, a coating device is used for coating the fabric, the fabric is conveyed through a coating roller in the coating processing process, the fabric is coated by the coating on the surface of the coating roller in the conveying process, the contact area between the fabric and the coating roller is limited, and the coating roller rotates at a higher rotating speed along with the acceleration of the coating efficiency, so that the contact time between the fabric and the surface of the coating roller is reduced, the coating on the surface of the coating roller is difficult to fully contact with the fabric, and the coating effect of the spinning surface is affected.

Disclosure of Invention

The invention aims to provide a fabric coating device and a fabric coating method based on radial extrusion opposite feeding so as to solve the problems in the prior art.

In order to achieve the above purpose, the present invention provides the following technical solutions: fabric coating device and coating method based on radial extrusion opposite feeding, wherein the fabric preparation method is prepared by coating through a preparation device: wherein the preparation device comprises: the coating pond is symmetrically provided with two groups of first L-shaped plates and second L-shaped plates, the first L-shaped plates and the second L-shaped plates are symmetrically arranged on the coating pond, lifting components for lifting the first L-shaped plates are arranged on the coating pond, guiding components for guiding in the lifting process are arranged on the second L-shaped plates, coating components for coating fabrics are arranged on the first L-shaped plates and the second L-shaped plates, two mutually symmetrically arranged strip-shaped plates are connected on the coating pond through a first connecting component, an extrusion component for extruding after coating fabrics is arranged between the two strip-shaped plates, a supporting component for supporting in the coating process of the fabrics is arranged on the two strip-shaped plates and the coating pond, and stirring components for preventing slurry from precipitating in the coating process are arranged on the first L-shaped plates; the coating assembly comprises a first rotating shaft and a second rotating shaft which are rotatably connected to the first L-shaped plate and the second L-shaped plate, a pushing roller is fixed on the first rotating shaft, a coating roller is fixed on the second rotating shaft, and the fabric passes through between the pushing roller and the coating roller and is propped against the pushing roller and the coating roller, and the lower part of the coating roller is positioned in the coating of the coating pool; the stirring assembly comprises a first fixed plate fixed on a first L-shaped plate, a driving shaft is rotationally connected to the first fixed plate, one end of the driving shaft is fixedly provided with stirring fan blades, a first motor used for driving the driving shaft is installed on the first fixed plate, the driving shaft is in transmission connection with a second rotating shaft through a transmission assembly, and an adjusting assembly used for adjusting the attaching area of the fabric and the coating roller in the high-speed stirring process is arranged on the first L-shaped plate; the transmission assembly comprises a first conical tooth fixed on the second rotating shaft, a second conical tooth is fixed on the driving shaft, and the first conical tooth and the second conical tooth are meshed with each other; the adjusting assembly comprises a second fixing plate arranged on one side of a first L-shaped plate and a second L-shaped plate, an adjusting roller is rotatably connected between the second fixing plates, third fixing plates are respectively fixed on the first L-shaped plate and the second L-shaped plate, first T-shaped rods are connected to the third fixing plates in a sliding mode, one ends of the first T-shaped rods are respectively fixed with the second fixing plates, a first spring is sleeved on the outer portion of the first T-shaped rods, and a pushing assembly used for pushing the second fixing plates is arranged on the first L-shaped plates.

Preferably, the pushing assembly comprises a rectangular plate, a second connecting assembly used for connecting the rectangular plate is arranged on the first L-shaped plate, a transmission plate is fixed on one side of the rectangular plate, a first inclined plane is arranged on the transmission plate, a first fixing pin is fixed on the second fixing plate, the first inclined plane and the first fixing pin are propped against each other, a lantern ring is fixed on the driving shaft, a plurality of moving assemblies used for moving the rectangular plate are arranged on the lantern ring, and a pulling assembly used for pulling the strip-shaped plate in the adjustment process is arranged between the rectangular plate and the strip-shaped plate.

Preferably, the pulling assembly comprises a Z-shaped plate fixed on the rectangular plate, a pushing plate is fixed at one end of the Z-shaped plate far away from the rectangular plate, a second inclined plane is formed in the pushing plate, a connecting plate is fixed at the lower end of the strip-shaped plate, a second fixing pin is fixed on the connecting plate, and the second fixing pin is propped against the second inclined plane.

Preferably, the second connecting assembly comprises two fourth fixing plates fixed on the first L-shaped plate, two second T-shaped rods are connected to the fourth fixing plates in a sliding mode, one ends of the two second T-shaped rods are fixed to the rectangular plate, and second springs are sleeved on the outer portions of the two second T-shaped rods.

Preferably, the moving assembly comprises sleeves, each sleeve is connected with a round rod in a sliding mode, one end, far away from the sleeve, of each round rod is fixed with a knocking pin, and a connecting spring used for connecting the round rods is arranged in the sleeve.

Preferably, the lifting assembly comprises a threaded rod rotatably connected to the first L-shaped plate, a threaded pipe is connected to the threaded rod in a threaded engagement manner, one end of the threaded pipe is fixed to the upper end of the coating pond, and a second motor for driving the threaded rod is arranged at the upper end of the first L-shaped plate; the guide assembly comprises a first sleeve fixed at the upper end of the coating pond, a first sliding rod is connected to the first sleeve in a sliding mode, and one end of the first sliding rod is fixed with the second L-shaped plate.

Preferably, the first connecting assembly comprises a square groove formed in the coating pond, a plurality of second sleeves are fixed at the lower end of the strip-shaped plate, second slide bars are connected to the second sleeves in a sliding mode, one ends, far away from the second sleeves, of the second slide bars are fixed with the square groove, and third springs used for connecting the second slide bars are arranged in the second sleeves.

Preferably, the support assembly comprises two support plates which are fixed at the upper ends of the strip-shaped plate and the coating pool and are symmetrically arranged, an installation shaft is rotatably connected between the two support plates, and a support roller for supporting the fabric is fixed on the installation shaft.

Preferably, the extrusion subassembly is including fixing the L type frame on two strip shaped plates, two be fixed with the stripper plate between the L type frame, a plurality of flowing back holes have been seted up on the stripper plate, two the top of strip shaped plate is connected with the roof through third coupling assembling, the balancing weight has been placed to the upper end of roof, the lower extreme of roof is fixed with the mounting bracket, rotate between the mounting bracket and be connected with the circle axle, be fixed with the squeeze roll to the face fabric extrusion ejection of compact after the coating on the circle axle.

Preferably, the third connecting assembly comprises a plurality of third sleeves fixed on the strip-shaped plate, each third sleeve is connected with a third sliding rod in a sliding manner, one end of each third sliding rod is fixed with the top plate, and a mounting spring for mounting and connecting the third sliding rods is arranged in the third sleeves.

Compared with the prior art, the invention has the beneficial effects that:

1. according to the fabric coating device based on radial extrusion opposite feeding, through the mutual matching of the pushing component, the adjusting component, the transmission component, the stirring component and the coating component, when the fabric is required to be conveyed at a higher speed, the two second fixing plates are enabled to move downwards along with the approaching movement stress of the rectangular plate, in the process of the downward movement of the two second fixing plates, the fabric in the conveying process is pushed to move towards the coating roller by the adjusting roller, the contact area between the fabric in the conveying process and the surface of the coating roller is increased, the full propping contact between the fabric and the surface of the coating roller can still be ensured in the high-speed rotation process of the coating roller, and the high-quality coating processing of the fabric is facilitated;

2. according to the fabric coating device based on radial extrusion opposite feeding, through the arrangement of the extrusion assembly, the extrusion roller on the mounting frame radially extrudes the fabric between the extrusion roller and the extrusion plate, so that redundant coating coated on the fabric is extruded out and flows back to the inside of the coating pool through the liquid discharge hole, and the waste of the coating is reduced;

3. this kind of surface fabric coating device based on radial extrusion subtend pay-off, the symmetry setting of two coating ponds makes two surface fabrics carry out the subtend and carries, laminating processing behind the coating of two different surface fabrics of being convenient for.

Drawings

FIG. 1 is a schematic diagram of the overall outline structure of the present invention;

FIG. 2 is a schematic view of the structure of the lifting assembly, the guiding assembly, the supporting assembly, the pressing assembly and the third connecting assembly according to the present invention;

FIG. 3 is a schematic view of a coating assembly and an adjusting assembly according to the present invention;

FIG. 4 is a schematic view of the structure of the stirring assembly, the transmission assembly, the adjusting assembly, the pushing assembly, the second connecting assembly, the moving assembly and the pulling assembly according to the present invention;

FIG. 5 is a schematic view of the structure of the pressing assembly and the pulling assembly of the present invention;

FIG. 6 is an enlarged schematic view of FIG. 2A;

FIG. 7 is an enlarged schematic view of the structure shown at B in FIG. 2;

FIG. 8 is an enlarged schematic view of FIG. 2C;

FIG. 9 is an enlarged schematic view of the structure of FIG. 3D;

FIG. 10 is an enlarged schematic view of the structure of FIG. 4 at E;

fig. 11 is an enlarged schematic view of the structure at F in fig. 5.

In the figure: 1. a coating pool; 2. a fabric; 3. a first L-shaped plate; 4. a second L-shaped plate; 5. a lifting assembly; 501. a threaded rod; 502. a threaded tube; 503. a second motor; 6. a guide assembly; 601. a first sleeve; 602. a first slide bar; 7. a coating assembly; 701. a first rotating shaft; 702. a pushing roller; 703. a second rotating shaft; 704. a coating roller; 8. a strip-shaped plate; 9. a first connection assembly; 901. a square groove; 902. a second sleeve; 903. a second slide bar; 904. a third spring; 10. a support assembly; 1001. a support plate; 1002. a mounting shaft; 1003. a support roller; 11. an extrusion assembly; 1101. an L-shaped frame; 1102. an extrusion plate; 1103. a liquid discharge hole; 1104. a top plate; 1105. balancing weight; 1106. a mounting frame; 1107. a circular shaft; 1108. a squeeze roll; 12. a third connection assembly; 1201. a third sleeve; 1202. a third slide bar; 13. a stirring assembly; 1301. a first fixing plate; 1302. a drive shaft; 1303. stirring fan blades; 1304. a first motor; 14. a transmission assembly; 1401. a first bevel gear; 1402. a second bevel gear; 15. an adjustment assembly; 1501. a second fixing plate; 1502. an adjusting roller; 1503. a third fixing plate; 1504. a first T-bar; 1505. a first spring; 16. a pushing assembly; 1601. a rectangular plate; 1602. a drive plate; 1603. a first inclined surface; 1604. a first fixing pin; 17. a second connection assembly; 1701. a fourth fixing plate; 1702. a second T-bar; 1703. a second spring; 18. a collar; 19. a moving assembly; 1901. a sleeve; 1902. a round bar; 1903. a connecting spring; 1904. knocking the pin; 20. pulling the assembly; 2001. a Z-shaped plate; 2002. a push plate; 2003. a second inclined surface; 2004. a connecting plate; 2005. and a second fixing pin.

Detailed Description

The following description of the embodiments of the present invention will be made clearly and completely with reference to the accompanying drawings, in which it is apparent that the embodiments described are only some embodiments of the present invention, but not all embodiments. All other embodiments, which can be made by those skilled in the art based on the embodiments of the invention without making any inventive effort, are intended to be within the scope of the invention.

Referring to fig. 1 to 11, the present invention provides a technical solution: fabric coating device and coating method based on radial extrusion opposite feeding, wherein the fabric preparation method is prepared by coating through a preparation device: wherein the preparation device comprises: the coating pond 1 is symmetrically provided with two groups, the coating pond 1 is provided with a first L-shaped plate 3 and a second L-shaped plate 4, the first L-shaped plate 3 and the second L-shaped plate 4 are symmetrically arranged, the coating pond 1 is provided with a lifting component 5 for lifting the first L-shaped plate 3, the second L-shaped plate 4 is provided with a guiding component 6 for guiding in the lifting process, the first L-shaped plate 3 and the second L-shaped plate 4 are provided with a coating component 7 for coating the fabric 2, the coating pond 1 is connected with two strip-shaped plates 8 which are symmetrically arranged through a first connecting component 9, an extrusion component 11 for extruding the fabric 2 after being coated is arranged between the two strip-shaped plates 8, the two strip-shaped plates 8 and the coating pond 1 are provided with a supporting component 10 for supporting in the fabric 2 coating process, and the first L-shaped plate 3 is provided with a stirring component 13 for preventing slurry from precipitating in the coating process; the coating assembly 7 comprises a first rotating shaft 701 and a second rotating shaft 703 which are rotatably connected to the first L-shaped plate 3 and the second L-shaped plate 4, wherein a push roller 702 is fixed on the first rotating shaft 701, a coating roller 704 is fixed on the second rotating shaft 703, and the fabric 2 passes through between the push roller 702 and the coating roller 704 and is propped against the push roller 702 and the coating roller 704, and the lower part of the coating roller 704 is positioned in the coating of the coating pool 1; the stirring assembly 13 comprises a first fixing plate 1301 fixed on a first L-shaped plate 3, a driving shaft 1302 is rotatably connected to the first fixing plate 1301, a stirring fan blade 1303 is fixed at one end of the driving shaft 1302, a first motor 1304 used for driving the driving shaft 1302 is installed on the first fixing plate 1301, the driving shaft 1302 is in transmission connection with a second rotating shaft 703 through a transmission assembly 14, and an adjusting assembly 15 used for adjusting the attaching area of the fabric 2 and the coating roller 704 in the high-speed stirring process is arranged on the first L-shaped plate 3; the transmission assembly 14 comprises a first conical tooth 1401 fixed on the second rotating shaft 703, a second conical tooth 1402 is fixed on the driving shaft 1302, and the first conical tooth 1401 and the second conical tooth 1402 are meshed with each other; the adjusting component 15 comprises second fixed plates 1501 arranged on one side of the first L-shaped plate 3 and one side of the second L-shaped plate 4, an adjusting roller 1502 is rotationally connected between the two second fixed plates 1501, third fixed plates 1503 are respectively fixed on the first L-shaped plate 3 and the second L-shaped plate 4, first T-shaped rods 1504 are connected to the two third fixed plates 1503 in a sliding mode, one ends of the two first T-shaped rods 1504 are respectively fixed with the second fixed plates 1501, first springs 1505 are sleeved on the outer portions of the two first T-shaped rods 1504, a pushing component 16 used for pushing the second fixed plates 1501 is arranged on the first L-shaped plate 3, the pushing component 16, the adjusting component 15, the transmission component 14, the stirring component 13 and the coating component 7 are matched with each other, when the fabric 2 needs to be conveyed at a higher speed, the two second fixed plates 1501 move downwards along with the approaching movement of the rectangular plates 1601, in the process of the downward movement of the two second fixed plates 1501, the fabric 2 in the process of pushing the adjusting roller 1502 is pushed by the fabric 2 in the conveying roller 704 to move towards the conveying roller 704, the fabric 704 can be fully contacted with the surface of the fabric 704 in the process, and the fabric can be coated surface 704 in the process of high-speed, and the fabric can be fully contacted with the fabric 704, and the surface of the fabric can be coated by the fabric in the surface of the high-contacting process, and the fabric can be fully guaranteed, and the surface of the fabric can be coated by the surface in the surface, and the fabric, and the surface can be coated by the surface.

The specific preparation method comprises the following steps: in the process of coating preparation processing of the fabric, the fabric 2 passes through the coating pool 1, in the process of passing through the coating pool 1, the fabric 2 passes through between the pushing roller 702 and the coating roller 704 and is respectively abutted against the pushing roller 702 and the coating roller 704, in the process of passing through the coating pool 1, the fabric 2 passes through between the extrusion roller 1108 and the extrusion plate 1102 and between the two supporting rollers 1003 on the two supporting components 10, and the supporting effect of the two supporting rollers 1003 on the two supporting components 10 supports the fabric 2 in the coating process, so that the fabric 2 is prevented from being polluted by contact and abutted against other objects after being fed and coated; after the fabric 2 is threaded, coating processing is carried out on the fabric 2, in the processing process, a driving shaft 1302 is driven to rotate through a first motor 1304, in the rotating process of the driving shaft 1302, a stirring fan blade 1303 at one end of the driving shaft 1302 is driven to rotate in the coating tank 1, and the coating in the coating tank 1 is stirred through the rotation of the stirring fan blade 1303, so that uneven coating caused by standing and precipitation of the coating in the coating tank 1 in the coating process is avoided, and the coating effect is ensured; and in the course of rotating the drive shaft 1302, drive the second awl tooth 1402 to rotate, in the course of rotating the second awl tooth 1402, through the mutual engagement transmission between first awl tooth 1401 and the second awl tooth 1402, drive the second spindle 703 and coating roller 704 on the second spindle 703 to rotate, because the facing material 2 keeps being in contact with coating roller 704 and pushing roller 702, carry on the facing material 2 along with the rotation of coating roller 704, and in the course of carrying, because the lower part of coating roller 704 is in the coating inside of coating pool 1, make the surface of coating roller 704 adhere to the coating along with the rotation of coating roller 704, and along with the counterbalance transport of coating roller 704 to facing material 2, make the coating on the surface of coating roller 704 adhere to facing material 2, thus carry on the coating processing to facing material 2; in the process of coating processing, the second motor 503 is started to drive the threaded rod 501 to rotate, in the process of rotating the threaded rod 501, the first L-shaped plate 3 and the second L-shaped plate 4 are driven to synchronously lift on the coating pool 1 through the mutual meshing transmission between the threaded rod 501 and the threaded pipe 502 and the guiding action of the first sleeve 601 and the first slide bar 602, the supporting force of the pushing roller 702 on the fabric 2 is adjusted through the synchronous lifting of the first L-shaped plate 3 and the second L-shaped plate 4, so that the fabric 2 is convenient to be conveyed by different extrusion forces, the fabric 2 is ensured to be always in a tight state in the conveying process, in the process of coating and conveying the fabric 2, the pressure of the top plate 1104 is realized through the plurality of balancing weights 1105 on the top plate 1104, the extrusion roller 1108 on the mounting bracket 1106 radially extrudes the fabric 2 between the extrusion roller 1108 and the extrusion plate 1102, redundant coating materials after coating on the fabric 2 are enabled to be back flowed into the coating pool 1 through the liquid discharge holes 1103, and the waste of the coating materials is reduced; during the rotation of the driving shaft 1302, the collar 18 is driven to rotate synchronously, during the rotation of the collar 18, the round rods 1902 on the sleeves 1901 are driven to move towards the outside of the sleeves 1901 under the action of centrifugal force, when the fabric 2 needs to be conveyed at a higher speed to improve the coating efficiency, the driving shaft 1302 and the coating roller 704 are driven to rotate at a higher rotating speed through the transmission of the first motor 1304 and the transmission assembly 14, during the rotation of the driving shaft 1302 at the higher rotating speed, the centrifugal force borne by the round rods 1902 is increased and continuously slides on the sleeves 1901, and during the sliding of the round rods 1902, the knocking pins 1904 at one end of the round rods 1902 are enabled to be propped against the rectangular plate 1601 along with the rotation of the driving shaft 1302 and the sliding of the round rods 1902; through the offset of each knocking pin 1904 and the rectangular plate 1601 and the guiding action of the second connecting component 17, the rectangular plate 1601 is pushed to move, in the moving process of the rectangular plate 1601, through the interaction between the first inclined surface 1603 on the transmission plate 1602 and the first fixing pin 1604 and the guiding action of the first T-shaped rods 1504 on the two third fixing plates 1503 on the stressed second fixing plates 1501, the two second fixing plates 1501 move downwards along with the approaching movement of the rectangular plate 1601 under stress, in the force-down moving process of the two second fixing plates 1501, the fabric 2 in the conveying process is pushed by the adjusting roller 1502 to move against the coating roller 704, the contact area between the fabric 2 and the surface of the coating roller 704 in the conveying process is increased, the full offset contact between the fabric 2 and the surface of the coating roller 704 in the high-speed rotating process is still ensured, the high-quality coating processing of the fabric 2 is facilitated, in the moving process of the plate 1601, the push plate 2002 on one end of Z-shaped plate is driven to move synchronously, in the moving process of the push plate 2002, the fabric 2 is pushed by the second inclined surface of the second fixing pin 2003 and the guiding component 2005, the fabric 2 is pushed by the interaction between the second inclined surface of the second inclined surface and the second inclined surface of the second fixing pin, the supporting plate 1502 and the supporting plate 8 is continuously pushed by the adjusting roller 8, and the supporting plate 8 is continuously pushed by the adjusting roller 8 in the process of the adjusting roller 8, and the distance between the supporting plate 10 and the supporting plate 8 is continuously pushed by the supporting plate 8 in the moving between the supporting plate 2 and the supporting component 10 through the sliding component.

Referring to fig. 3, 4, 9 and 10, the pushing component 16 includes a rectangular plate 1601, a second connecting component 17 for connecting the rectangular plate 1601 is disposed on the first L-shaped plate 3, a transmission plate 1602 is fixed on one side of the rectangular plate 1601, a first inclined surface 1603 is disposed on the transmission plate 1602, a first fixing pin 1604 is fixed on the second fixing plate 1501, the first inclined surface 1603 is disposed against the first fixing pin 1604, a collar 18 is fixed on the driving shaft 1302, a plurality of moving components 19 for moving the rectangular plate 1601 are disposed on the collar 18, a pulling component 20 for pulling the strip-shaped plate 8 in the adjustment process is disposed between the rectangular plate 1601 and the strip-shaped plate 8, the rectangular plate 1601 is pushed to move through the moving component 19, and the two second fixing plates 1501 are forced to move downwards along with the approaching movement of the rectangular plate 1601 through the interaction between the first inclined surface 1603 on the transmission plate 1602 and the first fixing pin 1604 and the guiding action of the first T-shaped rods on the two third fixing plates 1503.

Referring to fig. 4, 9 and 11, the pulling assembly 20 includes a Z-shaped plate 2001 fixed on a rectangular plate 1601, a push plate 2002 is fixed at one end of the Z-shaped plate 2001 far away from the rectangular plate 1601, a second inclined plane 2003 is formed on the push plate 2002, a connecting plate 2004 is fixed at the lower end of the strip plate 8, a second fixing pin 2005 is fixed on the connecting plate 2004, the second fixing pin 2005 is arranged against the second inclined plane 2003, the push plate 2002 at one end of the Z-shaped plate 2001 is driven to move synchronously during the movement of the rectangular plate 1601, the strip plate 8 is driven to move downwards under stress by the interaction between the second inclined plane 2003 and the second fixing pin 2005 and the guiding action of the second sleeve 902 and the second sliding rod 903 on the strip plate 8, and the distance between the strip plate 8 and the adjusting roller 1502 is adjusted by the descending movement of the strip plate 8, so as to avoid deformation of the fabric 2 between the supporting assembly 10 and the adjusting roller 1502 due to the continuous supporting action of the supporting assembly 10 on the strip plate 8 during the pushing of the fabric 2.

Referring to fig. 4 and 10, the second connecting assembly 17 includes two fourth fixing plates 1701 fixed on the first L-shaped plate 3, the two fourth fixing plates 1701 are slidably connected with second T-shaped rods 1702, one ends of the two second T-shaped rods 1702 are fixed with the rectangular plate 1601, the second springs 1703 are sleeved on the outer parts of the two second T-shaped rods 1702, and the rectangular plate 1601 after being stressed is guided by the second T-shaped rods 1702 on the fourth fixing plates 1701.

Referring to fig. 4 and 10, the moving assembly 19 includes sleeves 1901, a round bar 1902 is slidingly connected to each sleeve 1901, a striking pin 1904 is fixed at an end of the round bar 1902 away from the sleeve 1901, a connecting spring 1903 for connecting the round bar 1902 is disposed inside the sleeve 1901, during rotation of the driving shaft 1302, the collar 18 is driven to rotate synchronously, during rotation of the collar 18, the round bar 1902 on each sleeve 1901 moves towards the outside of the sleeve 1901 under the action of centrifugal force, when the fabric 2 needs to be conveyed at a faster speed to improve coating efficiency, the driving shaft 1302 and the coating roller 704 are driven to rotate at a faster rotation speed by the transmission of the first motor 1304 and the transmission assembly 14, during rotation of the driving shaft 1302 at the faster rotation speed, the centrifugal force received by each round bar 1902 is increased and continuously slides on the sleeve 1901, during sliding of the round bar 1902, the striking pin 1904 at one end of each round bar 1902 is made to abut against the plate 1601 along with rotation of the driving shaft 1302 and sliding of the round bar 1902, and the rectangular plate 1601 moves through the abutting action of each striking pin 1904 against the plate 1601 and the second pushing assembly 17.

Referring to fig. 2, 6 and 7, the lifting assembly 5 includes a threaded rod 501 rotatably connected to the first L-shaped plate 3, a threaded pipe 502 is connected to the threaded rod 501 in a threaded engagement manner, one end of the threaded pipe 502 is fixed to the upper end of the coating tank 1, and a second motor 503 for driving the threaded rod 501 to rotate is installed at the upper end of the first L-shaped plate 3; the guiding component 6 comprises a first sleeve 601 fixed at the upper end of the coating pool 1, a first sliding rod 602 is slidably connected to the first sleeve 601, one end of the first sliding rod 602 is fixed to the second L-shaped plate 4, the second motor 503 is started in the coating processing process to drive the threaded rod 501 to rotate, in the threaded rod 501 rotating process, the first L-shaped plate 3 and the second L-shaped plate 4 are driven to synchronously lift on the coating pool 1 through the mutual meshing transmission between the threaded rod 501 and the threaded pipe 502 and the guiding action of the first sleeve 601 and the first sliding rod 602, and the supporting force of the pushing roller 702 on the fabric 2 is adjusted through the synchronous lifting of the first L-shaped plate 3 and the second L-shaped plate 4, so that the fabric 2 is convenient to be conveyed by different extrusion forces, and the fabric 2 is ensured to be always in a tight state in the conveying process.

Referring to fig. 2 and 8, the first connecting component 9 includes a square groove 901 formed on the coating tank 1, a plurality of second sleeves 902 are fixed at the lower end of the strip-shaped plate 8, second sliding rods 903 are slidably connected to each of the second sleeves 902, one end of each of the second sliding rods 903 far away from the second sleeve 902 is fixed to the square groove 901, a third spring 904 for connecting the second sliding rods 903 is disposed inside the second sleeve 902, and the movement of the strip-shaped plate 8 is guided by the plurality of second sleeves 902 and the second sliding rods 903.

Referring to fig. 2 and 8, the supporting assembly 10 includes two supporting plates 1001 fixed at the upper ends of the strip-shaped plate 8 and the coating tank 1 and symmetrically arranged with each other, a mounting shaft 1002 is rotatably connected between the two supporting plates 1001, a supporting roller 1003 for supporting the fabric 2 is fixed on the mounting shaft 1002, during the process of passing the fabric 2 through the coating tank 1, the fabric 2 passes through between the extruding roller 1108 and the extruding plate 1102 and between the two supporting rollers 1003 on the two supporting assemblies 10, and supports the fabric 2 during the coating process by the supporting action of the two supporting rollers 1003 on the two supporting assemblies 10, so as to avoid the pollution caused by contact and offset of the fabric 2 after feeding and coating with other objects.

Referring to fig. 8, the extrusion assembly 11 includes an L-shaped frame 1101 fixed on two strip-shaped plates 8, an extrusion plate 1102 is fixed between the two L-shaped frames 1101, a plurality of liquid discharge holes 1103 are formed in the extrusion plate 1102, a top plate 1104 is connected above the two strip-shaped plates 8 through a third connecting assembly 12, a balancing weight 1105 is placed at the upper end of the top plate 1104, a mounting frame 1106 is fixed at the lower end of the top plate 1104, a circular shaft 1107 is rotatably connected between the mounting frames 1106, an extrusion roller 1108 for extruding and discharging the fabric 2 after coating is fixed on the circular shaft 1107, and in the process of coating and conveying the fabric 2, the extrusion roller 1108 on the mounting frame 1106 radially extrudes the fabric 2 between the extrusion roller 1108 and the extrusion plate 1102 through the pressure of a plurality of balancing weights 1105 on the top plate 1104, so that redundant coating on the fabric 2 is extruded out and flows back to the inside of the coating tank 1 through the liquid discharge holes 1103, and the waste of the coating is reduced.

Referring to fig. 2 and 8, the third connecting assembly 12 includes a plurality of third sleeves 1201 fixed on the strip-shaped plate 8, a third sliding rod 1202 is slidably connected to each third sleeve 1201, one end of each third sliding rod 1202 is fixed to the top plate 1104, a mounting spring for mounting and connecting the third sliding rod 1202 is disposed inside the third sleeve 1201, and the movement of the top plate 1104 after being stressed is guided by the plurality of third sleeves 1201 and the third sliding rod 1202.

It will be evident to those skilled in the art that the invention is not limited to the details of the foregoing illustrative embodiments, and that the present invention may be embodied in other specific forms without departing from the spirit or essential characteristics thereof. The present embodiments are, therefore, to be considered in all respects as illustrative and not restrictive, the scope of the invention being indicated by the appended claims rather than by the foregoing description, and all changes which come within the meaning and range of equivalency of the claims are therefore intended to be embraced therein. Any reference sign in a claim should not be construed as limiting the claim concerned.

Furthermore, it should be understood that although the present disclosure describes embodiments, not every embodiment is provided with a separate embodiment, and that this description is provided for clarity only, and that the disclosure is not limited to the embodiments described in detail below, and that the embodiments described in the examples may be combined as appropriate to form other embodiments that will be apparent to those skilled in the art.

Claims

1. Facing material coating device based on radial extrusion subtend pay-off, its characterized in that includes: coating pond (1), coating pond (1) symmetry is provided with two sets of, be provided with first L template (3) and second L template (4) on coating pond (1), first L template (3) and second L template (4) symmetry set up each other, be provided with on coating pond (1) and be used for lifting assembly (5) of first L template (3) lift, be provided with direction subassembly (6) of lift in-process direction on second L template (4), be provided with on first L template (3) and second L template (4) and be used for coating subassembly (7) of surface fabric (2) coating, be connected with on coating pond (1) two strip templates (8) of mutual symmetry setting through first coupling assembling (9), two be provided with between strip templates (8) and carry out extruded extrusion subassembly (11) to surface fabric (2) coating back, two be provided with on strip template (8) and coating pond (1) and be used for supporting component (10) that support in the surface fabric (2) coating process, be provided with on first L template (3) and be used for preventing in-process thick liquids (13) stirring.

2. The facing coating device based on radial extrusion counter-feeding according to claim 1, characterized in that: the coating assembly (7) comprises a first rotating shaft (701) and a second rotating shaft (703) which are rotatably connected to the first L-shaped plate (3) and the second L-shaped plate (4), wherein a pushing roller (702) is fixed on the first rotating shaft (701), a coating roller (704) is fixed on the second rotating shaft (703), and the fabric (2) passes through between the pushing roller (702) and the coating roller (704) and is propped against the pushing roller (702) and the coating roller (704), and the lower part of the coating roller (704) is positioned in the coating of the coating pool (1); the stirring assembly (13) comprises a first fixing plate (1301) fixed on a first L-shaped plate (3), a driving shaft (1302) is rotatably connected to the first fixing plate (1301), one end of the driving shaft (1302) is fixedly provided with a stirring fan blade (1303), a first motor (1304) used for driving the driving shaft (1302) is mounted on the first fixing plate (1301), the driving shaft (1302) is in transmission connection with a second rotating shaft (703) through a transmission assembly (14), and an adjusting assembly (15) used for adjusting the attaching area of the fabric (2) and the coating roller (704) in the high-speed stirring process is arranged on the first L-shaped plate (3); the transmission assembly (14) comprises a first conical tooth (1401) fixed on the second rotating shaft (703), a second conical tooth (1402) is fixed on the driving shaft (1302), and the first conical tooth (1401) and the second conical tooth (1402) are meshed with each other; the adjusting component (15) comprises a second fixing plate (1501) arranged on one side of a first L-shaped plate (3) and a second L-shaped plate (4), two adjusting rollers (1502) are rotatably connected between the second fixing plates (1501), third fixing plates (1503) are respectively fixed on the first L-shaped plate (3) and the second L-shaped plate (4), first T-shaped rods (1504) are slidably connected on the third fixing plates (1503), one ends of the first T-shaped rods (1504) are respectively fixed with the second fixing plates (1501), first springs (1505) are sleeved on the outer parts of the first T-shaped rods (1504), and pushing components (16) for pushing the second fixing plates (1501) are arranged on the first L-shaped plates (3).

3. The facing coating device based on radial extrusion counter-feeding according to claim 2, characterized in that: the pushing assembly (16) comprises a rectangular plate (1601), a second connecting assembly (17) used for connecting the rectangular plate (1601) is arranged on the first L-shaped plate (3), a transmission plate (1602) is fixed on one side of the rectangular plate (1601), a first inclined surface (1603) is arranged on the transmission plate (1602), a first fixing pin (1604) is fixed on the second fixing plate (1501), the first inclined surface (1603) is arranged against the first fixing pin (1604), a lantern ring (18) is fixed on the driving shaft (1302), a plurality of moving assemblies (19) used for moving the rectangular plate (1601) are arranged on the lantern ring (18), and a pulling assembly (20) used for pulling the strip-shaped plate (8) in the adjustment process is arranged between the rectangular plate (1601) and the strip-shaped plate (8).

4. A facing coating apparatus based on radial extrusion counter-feeding as claimed in claim 3, wherein: the pulling assembly (20) comprises a Z-shaped plate (2001) fixed on a rectangular plate (1601), a push plate (2002) is fixed at one end, far away from the rectangular plate (1601), of the Z-shaped plate (2001), a second inclined surface (2003) is formed in the push plate (2002), a connecting plate (2004) is fixed at the lower end of the strip-shaped plate (8), a second fixing pin (2005) is fixed on the connecting plate (2004), and the second fixing pin (2005) is propped against the second inclined surface (2003); the second connecting assembly (17) comprises two fourth fixing plates (1701) fixed on the first L-shaped plate (3), the two fourth fixing plates (1701) are connected with second T-shaped rods (1702) in a sliding mode, one ends of the two second T-shaped rods (1702) are fixed with the rectangular plate (1601), and second springs (1703) are sleeved on the outer portions of the two second T-shaped rods (1702).

5. The facing coating device based on radial extrusion counter-feeding as claimed in claim 4, wherein: the movable assembly (19) comprises sleeves (1901), each sleeve (1901) is connected with a round rod (1902) in a sliding mode, one end, far away from the sleeve (1901), of each round rod (1902) is fixed with a knocking pin (1904), and a connecting spring (1903) used for connecting the round rods (1902) is arranged inside the sleeve (1901).

6. The facing coating device based on radial extrusion counter-feeding according to claim 2, characterized in that: the lifting assembly (5) comprises a threaded rod (501) rotatably connected to the first L-shaped plate (3), a threaded pipe (502) is connected to the threaded rod (501) in a threaded engagement manner, one end of the threaded pipe (502) is fixed with the upper end of the coating pond (1), and a second motor (503) for driving the threaded rod (501) to rotate is installed at the upper end of the first L-shaped plate (3); the guide assembly (6) comprises a first sleeve (601) fixed at the upper end of the coating tank (1), a first sliding rod (602) is connected to the first sleeve (601) in a sliding mode, and one end of the first sliding rod (602) is fixed with the second L-shaped plate (4).

7. The facing coating device based on radial extrusion counter-feeding according to claim 1, characterized in that: the first connecting assembly (9) comprises square grooves (901) formed in the coating pool (1), a plurality of second sleeves (902) are fixed at the lower end of the strip-shaped plate (8), second slide bars (903) are connected to the second sleeves (902) in a sliding mode, one ends, away from the second sleeves (902), of the second slide bars (903) are fixed with the square grooves (901), and third springs (904) used for connecting the second slide bars (903) are arranged inside the second sleeves (902).

8. The facing coating device based on radial extrusion counter-feeding according to claim 1, characterized in that: the support assembly (10) comprises two support plates (1001) which are fixed at the upper ends of the strip-shaped plate (8) and the coating pool (1) and are symmetrically arranged, an installation shaft (1002) is rotatably connected between the two support plates (1001), and a support roller (1003) for supporting the fabric (2) is fixed on the installation shaft (1002).

9. The facing coating device based on radial extrusion counter-feeding as claimed in claim 8, wherein: the extrusion assembly (11) comprises an L-shaped frame (1101) fixed on two strip-shaped plates (8), an extrusion plate (1102) is fixed between the L-shaped frames (1101), a plurality of liquid discharge holes (1103) are formed in the extrusion plate (1102), a top plate (1104) is connected above the two strip-shaped plates (8) through a third connecting assembly (12), a balancing weight (1105) is placed at the upper end of the top plate (1104), a mounting frame (1106) is fixed at the lower end of the top plate (1104), a circular shaft (1107) is rotatably connected between the mounting frames (1106), and an extrusion roller (1108) for extruding and discharging the surface material (2) after coating is fixed on the circular shaft (1107); the third connecting assembly (12) comprises a plurality of third sleeves (1201) fixed on the strip-shaped plate (8), each third sleeve (1201) is connected with a third sliding rod (1202) in a sliding mode, one end of each third sliding rod (1202) is fixed with the top plate (1104), and a mounting spring for mounting and connecting the third sliding rods (1202) is arranged inside the third sleeve (1201).

10. A coating method using the facing coating apparatus based on radial extrusion facing feed as claimed in any one of claims 1 to 9, characterized by comprising the steps of:

step one: the fabric (2) passes through the coating pool (1) through the preparation device, in the process of passing through the coating pool (1), the fabric (2) passes through the space between the pushing roller (702) and the coating roller (704) and is respectively propped against the pushing roller (702) and the coating roller (704), and the fabric (2) is supported in the coating process through the supporting action of the two supporting rollers (1003) on the two supporting components (10), so that the fabric (2) is prevented from being polluted after being fed and coated;

step two: stirring the paint in the coating tank (1) through rotation of the stirring fan blades (1303), driving the second rotating shaft (703) and the coating roller (704) on the second rotating shaft (703) to rotate in the process of rotating the driving shaft (1302), conveying the fabric (2) along with rotation of the coating roller (704) because the fabric (2) is kept against the coating roller (704) and the pushing roller (702), enabling the surface of the coating roller (704) to be attached with the paint in the coating tank (1) along with rotation of the coating roller (704), and enabling the paint on the surface of the coating roller (704) to be attached to the fabric (2) along with the abutting conveying of the coating roller (704), and carrying out coating processing on the fabric (2);

step three: when the fabric (2) needs to be conveyed at a higher speed to improve the coating efficiency, the driving shaft (1302) and the coating roller (704) are driven to rotate at a higher rotating speed through the transmission of the first motor (1304) and the transmission assembly (14), the centrifugal force born by each round rod (1902) is increased and continuously slides on the sleeve (1901) in the rotating process of the driving shaft (1302), the knocking pin (1904) at one end of each round rod (1902) is enabled to be propped against the rectangular plate (1601) along with the rotation of the driving shaft (1302) and the sliding of the round rod (1902), and the rectangular plate (1601) is pushed to move through the propping action of each knocking pin (1904) and the rectangular plate (1601) and the guiding action of the second connection assembly (17);

step four: in the moving process of the rectangular plate (1601), through the interaction between the first inclined surface (1603) on the transmission plate (1602) and the first fixing pin (1604) and the guiding effect of the first T-shaped rods (1504) on the two third fixing plates (1503) on the stressed second fixing plates (1501), the two second fixing plates (1501) move downwards along with the approaching movement stress of the rectangular plate (1601), and in the moving process of the two second fixing plates (1501) in the stress downwards, the fabric (2) in the conveying process is pushed by the adjusting roller (1502) to move towards the coating roller (704), the contact area between the fabric (2) in the conveying process and the surface of the coating roller (704) is increased, so that the coating roller (704) can still ensure sufficient contact between the fabric (2) and the surface of the coating roller (704) in the high-speed rotating process, and the high-quality coating processing of the fabric (2) is facilitated.