RU2035055C1 - Composition sensitive to ir laser radiation - Google Patents

Abstract

FIELD: optics. SUBSTANCE: composition includes, parts by mass: epoxy compound 100; bismuth oxychloride 1.0-3.5; antimony trioxide 6.0-2.8. EFFECT: increased sensitivity to IR laser radiation. 1 tbl

Description

 The invention relates to compositions sensitive to IR laser radiation, and can be used for recording optical information, as well as for the purposes of marking products of electronics, optical, watch industry.

 A known composition comprising an epoxy compound and bismuth oxychloride (1).

The disadvantage of this composition is the veil formation when exposed to radiation in the visible region of the spectrum, as well as the high flux density of infrared radiation (6 J / cm ² ), necessary to obtain a contrast image. In addition, to obtain images with an optical density of D 1.0, a sufficiently high content of bismuth oxychloride (20-30 wt.) In the composition is required, which leads to a significant increase in the cost of the composition.

 The purpose of the invention is to increase the sensitivity of the composition to infrared laser radiation.

This goal is achieved due to the fact that the composition is sensitive to infrared laser radiation, including an epoxy compound and bismuth oxyhalide, additionally contains antimony trioxide in the following ratio, wt. h. Epoxy compound 100 Bismuth oxychloride 12.0-3.5 Antimony trioxide 6.0-28
According to the invention, various compositions of compounds used for sealing various electrical products (enveloping thixotropic, powder, casting) were used as epoxy compounds. The preparation of the compounds is carried out according to OST 11.028.006-74. Epoxy compounds approved for use in electronic products. As the polymer binder according to the invention, epoxidian resins are used: ED-20, ED-5, ED-7 (GOST 10587-76), which are condensation products of epichlorohydrin with diphenylpropane in an alkaline medium.

EA epoxyaniline resin (TU 6-02-914-81) is the condensation product of aniline and epichlorohydrin in an alkaline medium, mol.m. 200, the content of epoxy groups 30%
Polyethylenepolyamine (TU 6-02-594-80), diethylene triamine (TU 6-02-916-81), hexa-methylenediamine (STU 12-10242-63), UP-0632 (TU 6-09-15) are used as a hardener. -222-76), UP-575 (VTU N 181-5-66), UP-583 (VTU N 182-5-66).

 The concentration of the components of the filler mixture is varied so that the total amount of fillers, including color-forming additives, ensures the preservation of the technological properties of the compound.

 PRI me R 1. The composition is sensitive to infrared radiation, obtained as follows: 2 wt. including bismuth oxychloride (TU 6-09-02-161-74) and 10 wt. including antimony trioxide (TU 6-09-3267-76) is mixed and added to 100 wt. including epoxy coating thixotropic compound of the following composition, wt.h.

Epoxydian resin brand ED-20 100
EA 100 Epoxyaniline Resin Tricresyl Phosphate 46
A mixture of fillers with pigment 73-124 Polyethylenepolamine 16-20 Diethylenetriamine 16-20.

 A mixture of fillers with pigment is prepared by mixing previously dried to a constant weight of the following components, parts by weight talc (TU 21-25-159-75) 65; mica (TU 21-25-23-75) 35; white soot (TU 6-18-184-74) 15; titanium dioxide (GOST 9808-75) 1; zinc white (GOST 202-76) 3; green phthalocyanine pigment (TU 6-14-408-76) 0.1.

The composition was mixed, applied to a substrate, allowed to stand for 4 hours at room temperature, then subjected to thermosetting for 2 hours at 120 ° ^C.

The sensitivity to IR laser radiation is estimated by the optical density of the blackening obtained as a result of exposure to IR radiation from a neodymium laser with λ 1.06 μm with an energy density of 0.4 and 0.6 J / cm ² and a pulse duration of 4 ^. 10 ^-8 p. As a result of exposure to a single pulse of radiation, the layer stains black. The optical density of the staining as a result of exposure to a single pulse is presented in the table.

 PRI me R s 2-10. The composition according to example 1, but a different content of color-forming additives (bismuth oxychloride and antimony trioxide). The properties of the composition are presented in the table.

PRI me R 11 (comparative). The composition according to example 6, but does not contain antimony trioxide. As experiments have shown, the use of the composition is impractical, since the formation of a contrast marking requires exposure to 3 pulses of infrared radiation with λ = 1.06 μm and an energy density of 0.6 J / cm ² .

PRI me R 12 (comparative). The composition according to example 1, but does not contain bismuth oxychloride. The use of the composition is impractical, since when exposed to 1 pulse of infrared radiation with an energy density of 0.6 J / cm ^{2 the} optical density of the color is 0.45.

 PRI me R 13. The composition according to example 1, but as the epoxy compound using a powder compound of the following composition, wt.h.

Epoxydian resin brand ED-7P 100
Hardener UP 0632 (TU 6-09-15-222-76) 2.2-2.4 Mixture of fillers 50-52
A mixture of fillers includes the following components, parts by weight tetrabromodiphenylpropane (TU 6-09-3906-77) 7; aluminum hydroxide (GOST 11841-76) 40; titanium dioxide (GOST 9808-75) 1.0; green phthalocyanine pigment (TU 6-14-408-76) 0.1.

For 100 parts by weight the specified compound is administered 3.5 wt.h. bismuth oxychloride and 20 parts by weight antimony trioxide. In a hydraulic press at a pressure of 28-30 MPa at ²⁵ ° C of the powder composition pressed flat tablet. Sensitivity to infrared radiation is carried out analogously to example 1. The data are presented in the table.

PRI me R s 14-17. Analogously to example 13, but a different ratio of BiOCl and Sb ₂ O ₃ . The data are given in the table.

 PRI me R 18. The composition according to example 1, but as the epoxy compound using a casting compound of the following composition, wt.h.

Epoxydian resin brand ED-20 100
A mixture of fillers with pigment 10.1 Polyethylene polyamine 8-10
A mixture of fillers with pigment is prepared previously by mixing the following components, wt. talc 3; mica 7; green phthalocyanine pigment 0.1.

To 100 parts by weight compound of the specified composition add 3 wt.h. bismuth oxychloride and 12 parts by weight antimony trioxide, mix thoroughly until a homogeneous composition is obtained, vacuum, pour into heated forms, and then solidify in the following mode: at room temperature for 6 hours, at 120 ^about 4 hours. The composition properties are presented in the table.

PRI me R 19. The composition according to example 18, but the different content of BoOCl and Sb ₂ O ₃ . The properties of the composition are shown in the table.

 PRI me R 20. The composition according to example 1, but as the epoxy compound using the compound UP-584 (STU N 118-5-66) of the following composition, wt. h

Epoxydian resin brand ED-5 100
Epoxy aniline resin brand EA 50
Sovol (STU 12-10-192-62) 50
Quartz vibrating mill (GOST 9077-59) 100
Modified
amine UP-575 (VTU N 181-5-66) 26
Modified
amine UP-583 (VTU N 182-5-66) 18.5
To 100 wt. including the compound add 2.0 wt.h. bismuth oxychloride and 25 wt. including antimony trioxide, mixed and applied to a substrate. Curing is carried out according to the following mode: exposure at room temperature for 24 hours, at 100 ° C. ^for 4 hours.

 PRI me R 21. The composition according to example 1, but as the epoxy compound using the compound K-115 (STU 30-14148-63) of the following composition, wt. h

ED-5 epoxy resin 100 MGF-9 polyester (TU MHP N BU-17-56) 20 Polyethylene polyamine 10
For 100 parts by weight the specified compound add 1.90 wt.h. BiOCl and 27 wt. including Sb ₂ O ₃ . Curing is carried out according to the following mode: at room temperature for 24 hours, at 120 ° C. ^for 3 hours. The properties of the composition are presented in the table.

 PRI me R 22. The composition according to example 1, but as the epoxy compound use the casting compound EZK-12 (see Handbook of plastics. / Ed. Garbar M.I. Kataev V.M. Akutina M.S. t. 11, M. Chemistry, 1969, p. 97) of the following composition, parts by weight

 ED-5 brand epoxy resin 100 Hexamethylenediamine 10 Styrene 10 Titanium dioxide 100.

To 100 parts by weight the specified compound add 1.3 wt.h. BiOCl and 19 parts by weight Sb ₂ O ₃ . Curing is carried out analogously to example 1. The properties of the composition are shown in the table.

 PRI me R 23 (prototype). The photosensitive composition is prepared on the basis of the UP-584 epoxy compound (VTU N 18-5-66). For 100 parts by weight 5 wt.h. bismuth oxychloride. Curing and testing of the composition is carried out analogously to example 20. Properties are shown in the table.

As follows from the table, the color of the layer after exposure to infrared radiation is low D. The experiments showed that at an energy density of 0.6 J / cm ² contrast marking is achieved only when 3 pulses are applied, which reduces the performance of the marking process.

Claims (1)

 A composition sensitive to infrared laser radiation, including an epoxy compound and bismuth oxychloride, characterized in that it additionally contains antimony trioxide in the following ratio, wt.h. Epoxy Compound 100
Bismuth oxychloride 1.0 3.5
Antimony trioxide 6.0 28

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