CN113665235A - Non-glue-feeling permeation type nano printing process - Google Patents

Abstract

A non-glue-feeling permeation type nano printing process comprises the following specific steps: s1, designing a printing pattern, and preparing a heat transfer film according to the obtained printing pattern; s2, sleeving the clothes to be printed on the mold in a matching manner; s3, pressing the heat transfer film on the part to be printed of the clothes through a limiting component; s4, placing the mold in printing equipment, and heating and vacuumizing the interior of the printing equipment; s5, taking out the printed mould, taking the printed clothes off the mould, and then continuing to execute S2-S4. The printing process provided by the invention is simple to operate, the clothes printed with the specific printing patterns can be efficiently and high-quality obtained, the patterns and the clothes are integrated, the patterns do not touch human skin, and the comfort level of the clothes after being worn is greatly improved.

Description

Non-glue-feeling permeation type nano printing process

Technical Field

The invention relates to the technical field of clothes processing, in particular to a non-glue-feeling permeable nano printing process.

Background

Clothes are a general term for clothes, shoes, ornaments and the like, and are often referred to as clothes. The definition of a garment in the national standard is: products which are sewn and worn on the human body to play a role of protection and decoration, also called as clothes; along with the development of society, people can not only meet the requirements of heating and shading bodies when wearing clothes, but also dress themselves for the purpose of decorating, so that specific patterns can be embroidered on cloth in advance during the production of the clothes to meet the decoration requirements of people; however, the patterns are embroidered on the cloth by using the needles and the threads, and people can feel the patterns by touching with hands after wearing the finished clothes, and in addition, if the patterns are directly contacted with the skin of the human body, the discomfort of people can be caused.

Disclosure of Invention

Objects of the invention

The printing process provided by the invention is simple in operation, can efficiently and high-quality obtain the clothes printed with the specific printing patterns, the patterns are integrated with the clothes, the patterns do not touch human skin, and the comfort level of the clothes after being worn is greatly improved.

(II) technical scheme

The invention provides a non-glue-feeling permeable nano printing process, which comprises the following specific steps of:

s1, designing a printing pattern, and preparing a heat transfer film according to the obtained printing pattern;

s2, sleeving the clothes to be printed on the mold in a matching manner;

s3, pressing the heat transfer film on the part to be printed of the clothes through a limiting component;

s4, placing the mold in printing equipment, and heating and vacuumizing the interior of the printing equipment;

s5, taking out the printed mould, taking the printed clothes off the mould, and then continuing to execute S2-S4.

Preferably, the temperature in the printing equipment in S4 is 80-180 ℃.

Preferably, the degree of vacuum in the printing apparatus in S4 is 3 to 50 KPa.

Preferably, the heat transfer film comprises a PET film, an ink layer, a printing layer and release paper;

one end of the ink layer is connected with the PET film, and the other end of the ink layer is connected with the printing layer; the other end of the printing layer is coated with colloid; the release paper is connected with the other end of the printing layer through the colloid.

Preferably, the printing equipment comprises a shell, a plurality of groups of heating devices, a plurality of mounting plates, a vacuumizing device and a control box;

the mounting plates are all positioned in the shell and are connected with the inner wall of the shell through a plurality of groups of connecting rods, the mounting plates are symmetrically distributed by taking the central axis of the shell as a center, and the mounting plates are pairwise arranged into a group; a placing rack for placing the die is arranged between each group of mounting plates in a sliding manner;

a plurality of groups of support columns are arranged on the lower end face of the shell, a temperature sensor is arranged in the shell, and a plurality of groups of openings for the plurality of groups of placing racks to be inserted into the shell in a sliding manner are arranged on the side end face of the shell;

the multiple groups of heating devices are all connected with the inner wall of the shell; the air inlet end of the vacuumizing device is communicated with the inside of the shell through a pipeline;

the control box is connected with the inner wall of the shell, a display screen and a key module are arranged on the control box, and a central processing unit is arranged in the control box; the central processing unit, the vacuumizing device, the plurality of groups of heating devices, the temperature sensor, the display screen and the key module are electrically connected.

Preferably, the device also comprises a plurality of groups of driving devices and a plurality of groups of control switches;

the driving ends of the driving devices are respectively penetrated into the shell in a sealing manner and connected with the placing frames, and the driving devices are used for respectively driving the placing frames to move in a reciprocating manner;

the plurality of groups of control switches, the plurality of groups of driving devices and the plurality of groups of placing racks are in one-to-one correspondence; the multiple groups of control switches are all connected with the outer end face of the shell, and the multiple groups of control switches, the multiple groups of driving devices and the central processing unit are electrically connected.

Preferably, each group of placing frames comprises a clip frame, two groups of sliding plates and a sealing plate; wherein, the end surfaces of the two mounting plates which are close to each other are provided with sliding chutes;

the two groups of sliding plates are respectively connected with the two groups of sliding grooves in a sliding manner, and the two groups of sliding plates are respectively connected with two ends of the rectangular frame, which are far away from each other; a plurality of groups of first placing blocks and second placing blocks used for placing the mold in a matched mode are arranged on the inner end face of the square-shaped frame;

the sealing plate is vertical to the two groups of sliding plates and is connected with one end of the square-shaped frame; under the working state, the end face of the sealing plate presses the outer end face of the shell.

Preferably, a sealing gasket is arranged on the end face of the sealing plate, which is tightly pressed against the outer end face of the shell.

Preferably, the projection shape of the mold is square; the first placing blocks are connected with the inner wall of one side of the clip frame, and a plurality of first placing grooves are formed in the first placing blocks; the second placing block is connected with the inner wall of the other side of the clip frame, and a second placing groove is formed in the second placing block;

a plurality of groups of limiting rods are arranged on one group of outer end faces of the die, a handheld rod is arranged on the other group of outer end faces of the die, the other two groups of outer end faces of the die and the upper and lower end faces of the die are in arc transition connection, and a plurality of groups of mounting grooves are respectively arranged on the upper and lower end faces of the die; a magnet for magnetically adsorbing and connecting the limiting component is detachably arranged in the mounting groove; under mould and the shape frame cooperation state of returning, the cooperation is placed respectively in the first standing groove of multiunit to the multiunit gag lever post, and handheld pole is placed in the second standing groove.

Preferably, each group of limiting assemblies comprises a pressing strip and two groups of pressing blocks; two groups of pressing blocks are respectively connected with two ends of the pressing strip, and the two groups of pressing blocks are respectively connected with two groups of magnets in a magnetic adsorption manner.

Compared with the prior art, the technical scheme of the invention has the following beneficial technical effects:

the printing process provided by the invention is simple in operation, can efficiently and high-quality obtain the clothes printed with the specific printing patterns, when in use, the prepared finished clothes is matched with the mould, the mould sleeved with the clothes is placed in the printing equipment, and the printing patterns on the heat transfer printing film are transferred to the clothes in a heating and pressurizing mode, so that the required printing patterns can be obtained at specific positions on the clothes, the attractiveness of the clothes is improved, the transferring effect of the printing patterns is good, and the finished clothes without glue feeling can be efficiently and quickly prepared; the patterns printed on the final finished product of the clothes are integrated with the clothes, and the patterns do not touch human skin, so that the comfort level of the clothes after being worn is greatly improved;

the invention also provides printing equipment for quickly printing and producing clothes, the equipment can process a plurality of clothes at one time, the clothes are matched with the pre-produced mould, and then the mould is placed in the equipment and is printed and produced at a specific temperature and a specific vacuum degree, so that the quality of the printed clothes is ensured; in addition, the heat transfer film provided by the invention is convenient to fix with clothes, so that the heat transfer film is prevented from deviating in the printing process to influence the printing quality of the clothes.

Drawings

Fig. 1 is a flow chart of a method of a non-glue-feel penetrating nano-printing process according to the present invention.

Fig. 2 is a schematic structural diagram of a printing device in a non-glue-sensing penetrating nano-printing process according to the present invention.

Fig. 3 is a front view of fig. 2 in a non-glue-sensing penetrating nano-printing process according to the present invention.

Fig. 4 is a schematic structural diagram of a placement frame in a non-glue-sensing penetrating nano-printing process according to the present invention.

Fig. 5 is a schematic structural diagram of a thermal transfer film in a non-glue-sensing penetrating nano-printing process according to the present invention.

Fig. 6 is a schematic structural diagram of a mold in a non-glue-sensing penetrating nano-printing process according to the present invention.

Fig. 7 is a top view of a mold in a non-glue-sensing penetrating nano-printing process according to the present invention.

Fig. 8 is a schematic block diagram of a printing device in a non-glue-sensing penetrating nano-printing process according to the present invention.

Reference numerals: 1. a housing; 2. a heating device; 3. mounting a plate; 4. placing a rack; 41. a clip frame; 42. a slide plate; 43. a first placing block; 44. a first placing groove; 45. a sealing plate; 46. a second placement block; 47. a second placing groove; 5. a vacuum pumping device; 6. a support pillar; 7. a control box; 8. a control switch; 9. a central processing unit; 10. a mold; 101. a limiting rod; 102. a hand-held wand; 103. mounting grooves; 11. a thermal transfer film; 111. a PET film; 112. an ink layer; 113. printing layer; 114. a colloid; 115. release paper; 12. a garment; 13. layering; 14. and (7) briquetting.

Detailed Description

In order to make the objects, technical solutions and advantages of the present invention more apparent, the present invention will be described in further detail with reference to the accompanying drawings in conjunction with the following detailed description. It should be understood that the description is intended to be exemplary only, and is not intended to limit the scope of the present invention. Moreover, in the following description, descriptions of well-known structures and techniques are omitted so as to not unnecessarily obscure the concepts of the present invention.

As shown in fig. 1 to 8, the non-glue-feel penetrating nano-printing process provided by the present invention comprises the following specific steps:

s1, designing a printing pattern, and preparing the heat transfer film 11 according to the obtained printing pattern;

s2, the clothes 12 to be printed are sleeved on the mould 10 in a matching way;

s3, pressing the heat transfer film 11 on the part to be printed of the clothes 12 through a limiting component;

s4, placing the mold 10 in a printing device, and heating and vacuumizing the interior of the printing device;

s5, the printed mold 10 is taken out, and the printed garment 12 is taken out of the mold 10, and then S2 to S4 are continuously performed.

In the invention, when in use, the prepared finished clothes 12 is matched with the mould 10, the mould 10 sleeved with the clothes is placed in printing equipment, and the printing pattern on the heat transfer film 11 is transferred to the clothes 12 in a heating and pressurizing mode, so that the required printing pattern can be obtained at the specific part on the clothes 12, the attractiveness of the clothes 12 is improved, the transfer printing effect of the printing pattern is good, and the finished clothes 12 without glue feeling can be efficiently and quickly prepared.

In an alternative embodiment, the temperature in the printing device in S4 is 80-180 ℃.

In an alternative embodiment, the degree of vacuum in the printing device in S4 is 3-50 KPa.

In an alternative embodiment, the thermal transfer film 11 includes a PET film 111, an ink layer 112, a print layer 113, and a release paper 115;

one end of the ink layer 112 is connected with the PET film 111, and the other end of the ink layer 112 is connected with the printing layer 113; the other end of the printing layer 113 is coated with a colloid 114; the release paper 115 is connected with the other end of the printing layer 113 through a colloid 114;

during the use, break away from type paper 115 and printing layer 113 and break away from, with printing layer 113 through the specific part of colloid 114 adhesion on clothes 12 that is equipped with, it can to reuse spacing subassembly with heat-transfer membrane 11 fix on clothes 12, easy operation convenient to use fixes heat-transfer membrane 11 and clothes 12 with convenient high efficiency.

In an alternative embodiment, the printing apparatus comprises a housing 1, a plurality of sets of heating devices 2, a plurality of mounting plates 3, a vacuum extractor 5 and a control box 7;

the mounting plates 3 are all positioned in the shell 1, the mounting plates 3 are connected with the inner wall of the shell 1 through a plurality of groups of connecting rods, the mounting plates 3 are symmetrically distributed by taking the central axis of the shell 1 as a center, and the mounting plates 3 are pairwise arranged into a group; a placing rack 4 for placing the mold 10 is arranged between each group of mounting plates 3 in a sliding manner;

a plurality of groups of support columns 6 are arranged on the lower end face of the shell 1, a temperature sensor is arranged in the shell 1, and a plurality of groups of openings for the plurality of groups of placing frames 4 to be inserted into the shell 1 in a sliding manner are arranged on the side end face of the shell 1;

the plurality of groups of heating devices 2 are all connected with the inner wall of the shell 1; the air inlet end of the vacuumizing device 5 is communicated with the inside of the shell 1 through a pipeline;

the control box 7 is connected with the inner wall of the shell 1, a display screen and a key module are arranged on the control box 7, and a central processing unit 9 is arranged in the control box 7; the central processing unit 9, the vacuumizing device 5, the plurality of groups of heating devices 2, the temperature sensor, the display screen and the key module are electrically connected;

during the use, pull out rack 4 from the opening on shell 1, place the mould 10 that has clothes 12 again on rack 4, push into shell 1 rack 4, use the button module to set for the operating parameter of multiunit heating device 2 and evacuating device 5 to heat and the evacuation in the shell 1, and then can print the processing to clothes 12 of putting on the multiunit rack 4.

In an alternative embodiment, a plurality of sets of driving devices and a plurality of sets of control switches 8 are further included;

the multiple groups of driving devices are connected with the outer end face of the shell 1, the driving ends of the multiple groups of driving devices penetrate into the shell 1 in a sealing mode and are connected with the multiple groups of placing frames 4, and the multiple groups of driving devices are used for driving the multiple groups of placing frames 4 to move in a reciprocating mode; wherein, the driving device is selected from but not limited to a hydraulic telescopic rod;

the plurality of groups of control switches 8, the plurality of groups of driving devices and the plurality of groups of placing frames 4 are in one-to-one correspondence; the multiple groups of control switches 8 are all connected with the outer end face of the shell 1, and the multiple groups of control switches 8, the multiple groups of driving devices and the central processor 9 are electrically connected;

during the use, through pressing control switch 8 control drive arrangement and driving rack 4 and slide between two mounting panels 3 to push out rack 4 from the shell 1 or pull in rack 4 in the shell 1, labour saving and time saving more.

In an alternative embodiment, each set of racks 4 comprises a frame 41, two sets of sliding plates 42 and a sealing plate 45; wherein, the end surfaces of the two mounting plates 3 which are close to each other are provided with chutes;

the two groups of sliding plates 42 are respectively connected with the two groups of sliding grooves in a sliding manner, and the two groups of sliding plates 42 are respectively connected with two ends of the rectangular frame 41 which are far away from each other; a plurality of groups of first placing blocks 43 and second placing blocks 46 used for placing the mold 10 in a matched manner are arranged on the inner end surface of the square frame 41;

the sealing plate 45 is vertical to the two groups of sliding plates 42, and the sealing plate 45 is connected with one end of the square-shaped frame 41; in an operating state, the end face of the sealing plate 45 compresses the outer end face of the housing 1, and a sealing gasket is arranged on the end face of the sealing plate 45 compressed with the outer end face of the housing 1, so that the sealing performance between the sealing plate 45 and the outer end face of the housing 1 is improved.

In an alternative embodiment, the projected shape of the mold 10 is square; wherein, the multiple groups of first placing blocks 43 are connected with the inner wall of one side of the square-shaped frame 41, and multiple groups of first placing grooves 44 are arranged on the multiple groups of first placing blocks 43; the second placing block 46 is connected with the inner wall of the other side of the square frame 41, and a second placing groove 47 is formed in the second placing block 46;

a plurality of sets of limiting rods 101 are arranged on one set of outer end faces of the mold 10, a handheld rod 102 is arranged on the other set of outer end faces of the mold 10, the other two sets of outer end faces of the mold 10 and the upper and lower end faces of the mold are in arc transition connection, and a plurality of sets of mounting grooves 103 are respectively arranged on the upper and lower end faces of the mold 10; a magnet for magnetically adsorbing and connecting the limiting component is detachably arranged in the mounting groove 103; under the matching state of the mold 10 and the clip frame 41, the multiple sets of limiting rods 101 are respectively matched and placed in the multiple sets of first placing grooves 44, and the handheld rod 102 is placed in the second placing groove 47;

further, the limiting rods 101 correspond to the first placing blocks 43 one by one, and at least two groups of limiting rods 101 are arranged.

In an alternative embodiment, each group of limiting assemblies comprises a pressing strip 13 and two groups of pressing blocks 14; two groups of pressing blocks 14 are respectively connected with two ends of the pressing strip 13, and the two groups of pressing blocks 14 are respectively connected with two groups of magnets in a magnetic adsorption manner;

further, the length value of the trim strip 13 is greater than that of the heat transfer film 11, and the trim strip 13 is made of high-temperature-resistant plastic materials;

when in use, the magnets are correspondingly arranged in the installation grooves 103 on the mould 10 according to the positions to be printed on the clothes 12; after the heat transfer film 11 is adhered to the position to be printed on the clothes 12 correspondingly, the heat transfer film 11 is pressed by the pressing strips 13, and the two groups of pressing blocks 14 are respectively connected with the two groups of magnets in a magnetic adsorption mode so as to press the heat transfer film 11 on the clothes 12.

It is to be understood that the above-described embodiments of the present invention are merely illustrative of or explaining the principles of the invention and are not to be construed as limiting the invention. Therefore, any modification, equivalent replacement, improvement and the like made without departing from the spirit and scope of the present invention should be included in the protection scope of the present invention. Further, it is intended that the appended claims cover all such variations and modifications as fall within the scope and boundaries of the appended claims or the equivalents of such scope and boundaries.

Claims (10)

1. A non-glue-feeling permeation type nano printing process is characterized by comprising the following specific steps:

s1, designing a printing pattern, and preparing a heat transfer film (11) according to the obtained printing pattern;

s2, the clothes (12) to be printed are sleeved on the mould (10) in a matching way;

s3, pressing the heat transfer film (11) on the part to be printed of the garment (12) through a limiting component;

s4, placing the mold (10) in the printing equipment, and heating and vacuumizing the interior of the printing equipment;

s5, taking out the printed mould (10), taking the printed clothes (12) off the mould (10), and then continuing to execute S2-S4.

2. The non-gel permeation nano printing process according to claim 1, wherein the temperature in the printing equipment in S4 is 80-180 ℃.

3. The non-gel permeation nano printing process according to claim 1, wherein the vacuum degree in the printing equipment in S4 is 3-50 KPa.

4. The non-glue-feeling permeation type nano printing process according to claim 1, wherein the heat transfer film (11) comprises a PET film (111), an ink layer (112), a printing layer (113) and a release paper (115);

one end of the ink layer (112) is connected with the PET film (111), and the other end of the ink layer (112) is connected with the printing layer (113); the other end of the printing layer (113) is coated with a colloid (114); the release paper (115) is connected with the other end of the printing layer (113) through a colloid (114).

5. The non-glue-feeling osmotic nano-printing process according to claim 1, wherein the printing equipment comprises a housing (1), a plurality of groups of heating devices (2), a plurality of mounting plates (3), a vacuum extractor (5) and a control box (7);

the mounting plates (3) are all positioned in the shell (1), the mounting plates (3) are connected with the inner wall of the shell (1) through a plurality of groups of connecting rods, the mounting plates (3) are symmetrically distributed by taking the central axis of the shell (1) as a center, and the mounting plates (3) are pairwise arranged into a group; a placing rack (4) for placing the mold (10) is arranged between each group of mounting plates (3) in a sliding manner;

a plurality of groups of supporting columns (6) are arranged on the lower end face of the shell (1), a temperature sensor is arranged in the shell (1), and a plurality of groups of openings for the plurality of groups of placing frames (4) to be inserted into the shell (1) in a sliding manner are arranged on the side end face of the shell (1);

the multiple groups of heating devices (2) are all connected with the inner wall of the shell (1); the air inlet end of the vacuumizing device (5) is communicated with the inside of the shell (1) through a pipeline;

the control box (7) is connected with the inner wall of the shell (1), a display screen and a key module are arranged on the control box (7), and a central processor (9) is arranged in the control box (7); the central processing unit (9), the vacuumizing device (5), the plurality of groups of heating devices (2), the temperature sensor, the display screen and the key module are electrically connected.

6. The non-glue-sensitive penetrating nano-printing process according to claim 5, further comprising a plurality of sets of driving means and a plurality of sets of control switches (8);

the multiple groups of driving devices are connected with the outer end face of the shell (1), the driving ends of the multiple groups of driving devices penetrate into the shell (1) in a sealing mode and are connected with the multiple groups of placing frames (4), and the multiple groups of driving devices are used for driving the multiple groups of placing frames (4) to move in a reciprocating mode;

the plurality of groups of control switches (8), the plurality of groups of driving devices and the plurality of groups of placing frames (4) are in one-to-one correspondence; the multiple groups of control switches (8) are connected with the outer end face of the shell (1), and the multiple groups of control switches (8), the multiple groups of driving devices and the central processor (9) are electrically connected.

7. The process of claim 5, wherein each set of racks (4) comprises a frame (41), two sets of sliding plates (42) and a sealing plate (45); wherein, the end surfaces of the two mounting plates (3) which are close to each other are provided with chutes;

the two groups of sliding plates (42) are respectively connected with the two groups of sliding grooves in a sliding manner, and the two groups of sliding plates (42) are respectively connected with two ends of the square-shaped frame (41) which are far away from each other; a plurality of groups of first placing blocks (43) and second placing blocks (46) used for placing the die (10) in a matched mode are arranged on the inner end face of the square frame (41);

the sealing plate (45) is vertical to the two groups of sliding plates (42), and the sealing plate (45) is connected with one end of the square-shaped frame (41); in the working state, the end face of the sealing plate (45) presses the outer end face of the shell (1).

8. The non-glue-feeling osmotic nano printing process according to claim 7, wherein a sealing gasket is arranged on the end face of the sealing plate (45) pressed against the outer end face of the shell (1).

9. The process of claim 7, wherein the projection of the mold (10) is square; wherein, a plurality of groups of first placing blocks (43) are connected with the inner wall of one side of the clip-shaped frame (41), and a plurality of groups of first placing grooves (44) are arranged on the plurality of groups of first placing blocks (43); the second placing block (46) is connected with the inner wall of the other side of the square frame (41), and a second placing groove (47) is formed in the second placing block (46);

a plurality of groups of limiting rods (101) are arranged on one group of outer end faces of the mold (10), a handheld rod (102) is arranged on the other group of outer end faces of the mold (10), the other two groups of outer end faces of the mold (10) are in arc transition connection with the upper end face and the lower end face of the mold, and a plurality of groups of mounting grooves (103) are respectively arranged on the upper end face and the lower end face of the mold (10); a magnet for magnetically adsorbing and connecting the limiting component is detachably arranged in the mounting groove (103); under the matched state of the die (10) and the clip frame (41), a plurality of groups of limiting rods (101) are respectively matched and placed in a plurality of groups of first placing grooves (44), and the handheld rod (102) is placed in a second placing groove (47).

10. The process of claim 9, wherein each set of limiting elements comprises a batten (13) and two sets of compacts (14); two groups of pressing blocks (14) are respectively connected with two ends of the pressing strip (13), and the two groups of pressing blocks (14) are respectively connected with two groups of magnets in a magnetic adsorption manner.

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