CN105538941A

CN105538941A - Thermal transfer printing method

Info

Publication number: CN105538941A
Application number: CN201510973922.5A
Authority: CN
Inventors: 喻盛
Original assignee: Individual
Current assignee: Individual
Priority date: 2015-12-23
Filing date: 2015-12-23
Publication date: 2016-05-04
Anticipated expiration: 2035-12-23
Also published as: CN105538941B

Abstract

The invention discloses a thermal transfer printing method. An ink absorbing coating, a printing layer, a nano layer, a white transfer printing layer and a transfer printing base layer are printed on release paper, so that transfer printing release paper used for thermal transfer printing is obtained. The thermal transfer printing method has the advantages that a pattern with air vents can be printed on fabric or leather in a thermal transfer printing mode, and organic solvents harmful to the environment are avoided. Through holes in interspaces of gray scale screen dots can form the air vents, so that softness and comfort are achieved. The combination of ink-jet digital printing and screen printing adapts to intelligent production.

Description

A kind of heat-transferring method

Technical field

The present invention relates to a kind of heat-transferring method, particularly relate to a kind of heat-transferring method utilizing screen painting Binding number code printing.

Background technology

Hot transfer printing is also called xylopyrography, is a kind of method word be printed on heat-transferring printing paper or plastic foil or pattern be transferred to by the mode of heating pressurization on fabric or leather.Its advantage is that transferred image is bright in luster, levels are rich.Existing Thermal-printing Technology by whole piece graph transfer printing on target material, can only not have through hole to breathe freely, is not suitable for market demand.

Summary of the invention

In order to solve the problems of the technologies described above, the object of the invention is to provide a kind of heat-transferring method utilizing screen painting Binding number code printing.

A kind of heat-transferring method utilizing screen painting of the present invention, is characterized in that, comprise the following steps:

A), blotting coating is printed in release liners, after drying, forms ink-absorbed coated layer;

B), water-based spinning coating ink is printed on ink-absorbed coated layer by the mode that digital ink-jet prints, forms printable layer;

C), by white for nanometer transfer printing starch by screen painting on printable layer, dry formation nanometer layer;

D), by white hot transfer printing starch by screen painting in nanometer layer, the white transfer printing layer of dry formation;

E), transparent heat transfer printing slurry is formed transfer printing basic unit by screen painting on white transfer printing layer;

F), by TPU thermal fusing powder be evenly sprinkling upon in transfer printing basic unit, then dry process obtains being with figuratum transfer printing release liners;

G), be laid on transfer printing target material by the figuratum one side of transfer printing release liners band, control temperature is between 145-160 ° of C, and pressure, between 0.5-0.7mpa, continues 18-25 second, tears transfer printing release liners off after then cooling 10-15 minute.

Described dry run all maintains between 50-80 ° of C.

Described half tone is 120-180 order, linked network line 40-55 line/centimetre, gray scale is the site full figure layer of 45-55%.

Described blotting coating components comprises: pure water 70 ~ 80 weight portion, sodium carboxymethylcellulose CMC15 ~ 25 weight portion, flatting silica 2 ~ 3 weight portion, ethoxy urea 3 ~ 5 weight portion, defoamer 0.1 ~ 0.2 weight portion.

Described transparent heat transfer printing slurry component comprises: thermoplastic polyurethane aqueous dispersion 40-43 weight portion, VAE aqueous emulsion 40-43 weight portion, NMF 6-9 weight portion, emulsifying agent 2-3 weight portion, thickener 1-2 weight portion and defoamer 0.1-0.2 weight portion.

Described nanometer white transfer printing slurry component comprises: transparent heat transfer printing slurry 80-90 weight portion, NMF 6-9 weight portion, emulsifying agent 2-3 weight portion, thickener 1-2 weight portion, nanometer titanium dioxide 2-5 weight portion and defoamer 0.1-0.2 weight portion.

Described white hot transfer printing slurry component comprises: transparent heat transfer printing slurry 60-70 weight portion, NMF 6-9 weight portion, emulsifying agent 2-3 weight portion, thickener 1-2 weight portion, titanium dioxide 20-25 weight portion and defoamer 0.1-0.2 weight portion.

The invention has the advantages that on fabric or leather, the figure of air-vent can be had by thermal transfer ribbon, and without the organic solvent of hostile environment.The through hole of the gap of GTG site can form passage, soft comfortable.The combination of ink-jet digital printing and screen painting adapts to intelligent production.

Accompanying drawing explanation

Fig. 1 is method flow diagram of the present invention.

Detailed description of the invention

A kind of heat-transferring method utilizing screen painting of the present invention as shown in Figure 1, is realized by following steps:

By pure water 70 ~ 80 weight portion, sodium carboxymethylcellulose CMC15 ~ 25 weight portion, flatting silica 2 ~ 3 weight portion, ethoxy urea 3 ~ 5 weight portion, the blotting coating of defoamer 0.1 ~ 0.2 weight portion is printed in release liners, maintains between 50-80 ° of C and forms ink-absorbed coated layer after drying;

Water-based spinning coating ink is printed on ink-absorbed coated layer by the mode that digital ink-jet prints, forms printable layer;

By transparent heat transfer printing slurry 80-90 weight portion, NMF 6-9 weight portion, emulsifying agent 2-3 weight portion, thickener 1-2 weight portion, the white transfer printing slurry of nanometer of nanometer titanium dioxide 2-5 weight portion and defoamer 0.1-0.2 weight portion is by 120-180 order, linked network line 40-55 line/centimetre, gray scale be the screen painting of the site full figure layer of 45-55% on printable layer, to maintain between 50-80 ° of C and dryly form nanometer layer;

By transparent heat transfer printing slurry 60-70 weight portion, NMF 6-9 weight portion, emulsifying agent 2-3 weight portion, thickener 1-2 weight portion, the white hot transfer printing slurry of titanium dioxide 20-25 weight portion and defoamer 0.1-0.2 weight portion is by 120-180 order, linked network line 40-55 line/centimetre, gray scale be the screen painting of the site full figure layer of 45-55% in nanometer layer, to maintain between 50-80 ° of C and dryly form white transfer printing layer;

By thermoplastic polyurethane aqueous dispersion 40-43 weight portion, VAE aqueous emulsion 40-43 weight portion, NMF 6-9 weight portion, emulsifying agent 2-3 weight portion, the transparent heat transfer printing slurry of thickener 1-2 weight portion and defoamer 0.1-0.2 weight portion is by 120-180 order, linked network line 40-55 line/centimetre, gray scale is that the screen painting of the site full figure layer of 45-55% forms transfer printing basic unit on white transfer printing layer;

TPU thermal fusing powder is evenly sprinkling upon in transfer printing basic unit, then maintains dry process between 50-80 ° of C and obtain being with figuratum transfer printing release liners;

The figuratum one side of transfer printing release liners band is laid on transfer printing target material, control temperature is between 145-160 ° of C, and pressure, between 0.5-0.7mpa, continues 18-25 second, then tear transfer printing release liners off after cooling 10-15 minute, namely complete the process of whole hot transfer printing.

The transfer graphic obtained by the inventive method with air-vent, soft comfortable, and the present invention be applicable to industrial intelligentization produce.

For a person skilled in the art, according to technical scheme described above and design, other various corresponding change and distortion can be made, and all these change and distortion all should belong within the protection domain of the claims in the present invention.

Claims

1. a heat-transferring method, is characterized in that, comprises the following steps:

Blotting coating is printed in release liners, after drying, forms ink-absorbed coated layer;

White for nanometer transfer printing is starched by screen painting on printable layer, dry formation nanometer layer;

White hot transfer printing is starched by screen painting in nanometer layer, the white transfer printing layer of dry formation;

Transparent heat transfer printing slurry is formed transfer printing basic unit by screen painting on white transfer printing layer;

Evenly be sprinkling upon by TPU thermal fusing powder in transfer printing basic unit, then dry process obtains being with figuratum transfer printing release liners;

Be laid on transfer printing target material by the figuratum one side of transfer printing release liners band, control temperature is between 145-160 ° of C, and pressure, between 0.5-0.7mpa, continues 18-25 second, tears transfer printing release liners off after then cooling 10-15 minute.

2. method according to claim 1, is characterized in that, described dry run all maintains between 50-80 ° of C.

3. method according to claim 1, is characterized in that, described half tone is 120-180 order, linked network line 40-55 line/centimetre, gray scale is the site full figure layer of 45-55%.

4. method according to claim 1, is characterized in that, described blotting coating components comprises: pure water 70 ~ 80 weight portion, sodium carboxymethylcellulose CMC15 ~ 25 weight portion, flatting silica 2 ~ 3 weight portion, ethoxy urea 3 ~ 5 weight portion, defoamer 0.1 ~ 0.2 weight portion.

5. method according to claim 1, it is characterized in that, described transparent heat transfer printing slurry component comprises: thermoplastic polyurethane aqueous dispersion 40-43 weight portion, VAE aqueous emulsion 40-43 weight portion, NMF 6-9 weight portion, emulsifying agent 2-3 weight portion, thickener 1-2 weight portion and defoamer 0.1-0.2 weight portion.

6. method according to claim 5, is characterized in that, described nanometer white transfer printing slurry component comprises: transparent heat transfer printing slurry 80-90 weight portion, NMF 6-9 weight portion, emulsifying agent 2-3 weight portion, thickener 1-2 weight portion, nanometer titanium dioxide 2-5 weight portion and defoamer 0.1-0.2 weight portion.

7. method according to claim 5, is characterized in that, described white hot transfer printing slurry component comprises: transparent heat transfer printing slurry 60-70 weight portion, NMF 6-9 weight portion, emulsifying agent 2-3 weight portion, thickener 1-2 weight portion, titanium dioxide 20-25 weight portion and defoamer 0.1-0.2 weight portion.