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Printing system and method for glass high-temperature jet printing codes

A printing system and glass technology, applied in printing devices, copying/marking methods, printing, etc., can solve the problems of easy detachment of self-adhesive, 2-dimensional code color easily detached, short storage time, etc., to improve the batch pass rate , The effect of precise location and reduction of production costs

Pending Publication Date: 2022-05-27
英辉(大厂)自动化技术有限公司 +1
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  • Summary
  • Abstract
  • Description
  • Claims
  • Application Information

AI Technical Summary

Problems solved by technology

But the way of self-adhesive, the storage time is short, and the self-adhesive is easy to fall off after a long time
The color of the QR code is easy to fall off

Method used

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  • Printing system and method for glass high-temperature jet printing codes
  • Printing system and method for glass high-temperature jet printing codes
  • Printing system and method for glass high-temperature jet printing codes

Examples

Experimental program
Comparison scheme
Effect test

Embodiment 1

[0045] (1) Preparation of low-temperature glaze: SiO 2 20 copies, B 2 o 3 5 copies, Bi 2 o 3 35 parts, Al 2 o 3 1.5 parts, CuO 1 part, Cr 2 o 3 1.5 parts, ZrO 2 1 copy, K 2 O 0.5 parts, Na 2 O 1.5 parts, Li 2 O 1.5 parts; mix well, calcinate at 800°C for 1 hour to form a frit, take out the frit and crush it to below 300 mesh by ball milling to obtain the low-temperature glaze;

[0046] (2) Preparation of micro-nano glaze slurry: Mix 60 parts of low-temperature glaze prepared in step (1), 10 parts of dispersant, 5 parts of resin and 25 parts of cyclohexanone, and after uniform dispersion, fully grind with a sand mill, The particle size of the grinding zirconium beads used is between 0.3 and 1.0 mm, and the average particle size is 100 nm, and the maximum particle size is 600 nm.

[0047] (3) Add 85 parts of micro-nano glaze slurry prepared in step (2), 0.2 parts of leveling agent, 5 parts of resin, 5 parts of propylene glycol methyl ether acetate, and 5 parts ...

Embodiment 2

[0049] (1) Preparation of low-temperature glaze: SiO 2 40 copies, B 2 o 3 15 copies, Bi 2 o 3 55 parts, Al 2 o 3 4.5 parts, CuO 2.5 parts, Cr 2 o 3 5 parts, ZrO 2 4 copies, K 2 O 1.5 parts, Na 2 O 0.5 parts, Li 2 3 parts of O; mix well, calcinate at 900°C for 0.5h to form a frit, take out the frit and crush it to below 300 mesh by ball milling to obtain the low-temperature glaze;

[0050] (2) Preparation of micro-nano glaze slurry: Mix 60 parts of low-temperature glaze prepared in step (1), 10 parts of dispersant, 5 parts of resin and 25 parts of cyclohexanone, and after uniform dispersion, fully grind with a sand mill, The particle size of the grinding zirconium beads used is between 0.3 and 1.0 mm, and the average particle size is 300 nm, and the maximum particle size is 700 nm.

[0051] (3) Add 85 parts of micro-nano glaze slurry prepared in step (2), 0.2 parts of leveling agent, 5 parts of resin, 5 parts of propylene glycol methyl ether acetate, and 5 par...

Embodiment 3

[0053] (1) Preparation of low-temperature glaze: SiO 2 25 copies, B 2 o 3 10 copies, Bi 2 o 3 40 parts, Al 2 o 3 2.5 parts, CuO 3.5 parts, Cr 2 o 3 3.5 parts, ZrO 2 3 copies, K 2 O 1 part, Na 2 O 1 part, Li 2 2 parts of O; mix well, calcinate at 850°C for 1 hour to form a frit, take out the frit and crush it to below 300 mesh by ball milling to obtain the low-temperature glaze;

[0054] (2) Preparation of micro-nano glaze slurry: Mix 60 parts of low-temperature glaze prepared in step (1), 7 parts of dispersant, 8 parts of resin and 25 parts of cyclohexanone, after uniform dispersion, fully grind with a sand mill, The particle size of the grinding zirconium beads used is between 0.3 and 1.0 mm, and the average particle size is 300 nm, and the maximum particle size is 600 nm.

[0055] (3) Add 90 parts of micro-nano glaze slurry prepared in step (2), 0.2 parts of leveling agent, 5 parts of resin, 2 parts of propylene glycol methyl ether acetate, and 3 parts of dip...

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Abstract

The invention discloses a printing system and a printing method for high-temperature spray printing codes of glass. The printing system mainly comprises a conveying platform used for conveying glass to be printed; the positioning device is arranged above the conveying platform and adopts a visual positioning system, when to-be-printed glass reaches a designated position, the conveying platform stops conveying, and a camera of the visual positioning system performs shooting to determine the printing position of a jet printing code; the jet printing code printing device is arranged above the conveying platform and located behind the positioning device, when the to-be-printed glass continues to run to the position below a printing head of the jet printing code printing device, the printing head is used for finding the printing position where jet printing codes need to be printed, and the conveying platform drives the to-be-printed glass to move; the jet printing code printing device completes jet printing code printing; the detection device is arranged above the conveying platform and located behind the jet printing code printing device, and a code scanning gun of the detection device is used for conducting code scanning detection on jet printing codes of the printed glass. And one object with one code and no falling and color fading can be realized.

Description

technical field [0001] The invention relates to the field of glass production, in particular to a printing device and a printing method for high-temperature jet printing on glass. Background technique [0002] In the existing inkjet printing technology, one technology is to use the ink printed by the inkjet printer to print the ink on the glass with organic pigment ink. After printing, it cannot be tempered at high temperature, so this technology can be industrialized. The content on the glass after printing cannot really be fused with the glass, which cannot meet the requirements of tempered glass. [0003] The other is screen printing technology, which is to make plates and print plates first, and then use a screen printing machine or manual scraping screen to print on the glass. The requirements of this screen printing can meet the requirements of glass tempering, but it cannot be used on the assembly line. Digital production, such as data printing that cannot realize va...

Claims

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Application Information

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Patent Type & Authority Applications(China)
IPC IPC(8): B41J3/407B41J2/01B41J2/175B41J29/393B41J29/46B41J3/01B41J11/00B41M1/34B41M5/00C09D11/38
CPCB41J3/407B41J2/01B41J2/17503B41J29/393B41J29/46B41J3/01B41J11/00B41M1/34B41M5/0047B41M5/007B41M5/0023C09D11/38
Inventor 何凤刚何海峰
Owner 英辉(大厂)自动化技术有限公司