FI57072C - VAERMEKAENSLIGT KOPIERINGSARK MED BRETT OMRAODE - Google Patents

Description

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Iffly W <11) uTLAeGNINe $$ KRIFT 5 7072 C (4¾ Patent Il ·: ^ v ^ (51) Kv.iic.vint.ci. * B 41 M 5/18 ENGLISH - FINLAND (21) • '• »• "« »'»' '.Mut-Ptt «ntan * akninc 631 ^ 72 (22) Haktmltpilvi - AraAicnlnpdtf 09 · 03-72 (23) Alkupilvi - Glltlghattdaf 09.03-72 (41) Tullut fulklMksi - Bllvlt off« ntl (| 11.09 to 72

National Board of Patents and Registration .... ...... .... . .....

_ '. (44) Date of issue and date of issue. - or. no ftr.

Patent * och registerstyrelsen '' AimöIcm utiagd och utUkrtftM publicerad ^ yu ^ .ou (32) (33) (31) Requested «toilMus — iUfird prlorittt 10.03-71 USA (US) 123106 (71) Minnesota Mining and Manufacturing Company, 3M Center , Saint Paul, "Minnesota 55101, USA (72) Donald John Newman, White Bear Play, Minnesota, Donald John Williams,

White Bear Lake, Minnesota, John Richard Berg, St. Paul, Minnesota, USA (7 ^) 0y Kolster Ah (5U) Wide Heat Sensitive Copy Sheet - Värmekänsligt kopieringsark med Brett omr & de

The present invention relates to a heat-sensitive sheet material comprising, as a thin layer, a heat-sensitive composition on a carrier having a wide radiation flexibility, the composition producing a visible image when heated for imaging. The sheet material according to the invention can be used to produce projection films from semi-color originals using a thermographic copying method.

"The thermographic method, as described by Miller in U.S. Patent 2,7I + 0,896 (published March 3, 1956), comprises the original being subjected to short-term high-intensity irradiation. Thermally conductive contact with a heat-sensitive copy sheet. In such methods, a thermal pattern made using wide lines or thicker pattern areas can be formed faster than thinner lines or smaller areas, resulting in smearing of the former areas and partial copying of the latter areas if the copy sheet used does not have sufficient irradiation flexibility. 377, provide a dense black pattern, but the irradiation must be precisely adjusted to provide a usable degree of uniformity.More uniformity 57072 is achieved with copy sheet structures based on Ferri soaps, such as U.S. Patent 2,663 6 ^ k has been described, but even with these sheets it has been found difficult to achieve a completely satisfactory uniformity of both thin and thick lines or patterns.

It has now surprisingly been found that the combination of silver and Ferri soap provides a copy sheet structure which has superior uniformity when irradiated compared to sheets containing these compounds separately.

The sheet material according to the invention is characterized in that the composition consists of a mixture of iron (III) and silver soaps of long-chain fatty acids, the amount of silver soap being 10-00 by weight of the mixture, optionally a silver image toner and the phenol-coreactant of these soaps.

The sheet material according to the invention is capable of accurately copying both fine details and large-area images onto a single sheet, and provides excellent detailed projection films from halftone and other difficult-to-reproduce originals.

Heat-sensitive copying sheets containing silver soap form a visible image due to the redox reaction. A different reaction, presumably a chelating reaction, occurs in ferric soap coatings. In this case, different additional reagents can also be used, but it has been found possible to use the same additional reagent in both metal soap reagents. Compounds such as pyrogallic acid, catechol, protocatechinic acid, azelaylpyrogallic acid, azelayylbispyrogallic acid, methyl gallate and behenoylpyrogallol are very effective. Each of these compounds is a polyhydric phenol. Mixtures of these and other reactive foods can be used in metal soaps to obtain patterns with preferred color tones. Tinting agents, such as phthalazone, are known to improve the silver color tone in copy sheets based on silver soaps and have also been found to be advantageous in the products of the invention, e.g. in amounts of about 15 to 20% by weight of silver soap. Polymeric film-forming binders that do not melt at copying temperatures are usually used in amounts sufficient to provide a smooth and well-bonded coating.

The compositions may be applied to paper or other non-transparent substrate and thus, when used, may contain pignants, fillers and other additives. Very advantageous results have been obtained when using clear transparent coatings with transparent films, and the obtained copies are then excellently suitable as translucent projected films for use in projection equipment suitable for use.

The following examples, in which all parts are by weight unless otherwise indicated, further illustrate the invention.

Example 1

The first coating composition is prepared by mixing together 20 parts of a 20 # ethanol dispersion of ferristearate, 20 parts of a 20 # ethanol dispersion of silver behenate, 0.66 parts of phthalazinone, 66.66 parts of a 15 # polyvinyl acetate acetone solution and 88.5 parts of acetone. . The mixture is applied to a 0.05 mm polyethylene tert-phthalate-polyether film and so that the coating weight of the drying residue is 5.9 e / »·

A second coating mixture prepared by dissolving 20 parts of cellulose acetate butyrate and 1 * part of methyl gallate in 180 parts of methyl ethyl ketone is added to the first coating with a coating weight of 3.2 g / m after drying. Both of these coatings provide a thin, transparent, heat-sensitive layer.

The coated film is clear and transparent and has a color slightly resembling the color of the skin. Part of it is brought into surface contact with an original with black printed patterns on white paper. When irradiated for a short time through the film using strong radiant energy in a thermographic copier, the pattern is copied to the film. The darkness of the pattern is about 1.1. Patterns with a darkness of more than about 0.6 are effective in creating projection patterns that can be easily viewed in a lighted room.

Another part was used to make a copy of the printed semi-color original by the same method. The dark areas of the pattern were copied in dense black. The amplification of the lighter areas was much lower in darkness and purple in color.

Example 2

The silver soap dispersion is prepared by mixing 60 σea of silver behenate, 2i + 0 parts of ethanol, 75 parts of polyvinyl acetate, 11.25 parts of phthalazinone and 1089 parts of acetone.

The ferric soap dispersion is prepared in a similar manner by mixing together 60 parts of ferristearate, 2 parts of ethanol, 75 parts of polyvinyl acetate and 1100 parts of acetone.1 and the coatings are dried in an oven at a temperature not exceeding about 93 ° C. Each sample is then further coated with a mixture of 9.8 parts of cellulose acetate butyrate and 2.0 parts of methyl gallate in 88.2 parts of methyl ethyl ketone added through a 0.075 mm orifice and the sheet is dried again. The chic samples are thermographically copied by fitting them against the original, which has both wide and narrow lines and which is then irradiated with strong radiant energy, displacing at decreasing periods in the longitudinal direction of the lines. The test is suitably performed in a thermographic device in which the speed of movement of the copy sheet and the printed original past the linear strong radiation source is steadily increased, thus providing a graphical representation of the irradiation area.

57072

If processing times are too long, the copy will be smudged, »especially thick lines will widen and have rough and uneven edges. Using an irradiation time that is too short reduces the darkness of the copy and does not copy the finest lines in the pattern. The irradiation range between these extremes describes the flexibility of the copy sheet. The following table shows the relative proportions of such copy sheets. Numerical evaluation of its flexibility »made and tested as described above using 100% silver soap up to 100 pounds of ferric soap and 10% additions of ingredients.

Table I

Effect of Fe: Ag ratio on relative irradiance.

% Ag soap 0 10 20 30 1 * 0 50 60 70 80 90 100% Fe soap 100 90 80 70 60 50 1 * 0 30 20 10 0 flexibility. 33 37 1 * 0 1 * 6 1 * 7 52 50 51 50 l8 15

Surprisingly, the flexibility of mixtures containing 10-80% silver soap increases to a value which far exceeds that obtained with either soap alone.

Example 3 A 0.025 mm polyester film is provided with a dried first coating consisting of a mixture of equal amounts of ferric stearate and silver behenate together with a tinting agent and a binder, as described in Example 1. The film portions are then separately coated with mixtures containing 2 parts of various other reactants and 9 »Ö parts of cellulose acetate butyrate in 88.2 parts of methyl ethyl ketone, added through a 0.075 mm coating hole and dried again. The same coatings are added separately on top of the first coatings, each containing one metal soap for use as a reference. All samples are tested for irradiance as described above and the results are shown in the following table.

Table II

Effect of coreactant on relative irradiance

Co-reagent Relative irradiance

Ferri Silver Alloy azelayl-pyrogallic acid 23 12 27 protocatechinic acid 33 lU 38 pyrogallic acid 2U 11 1 * 6 methyl gallate 17 13 1 * 3 azelayl-bis-pyrogallic acid 23 16 29 catechol 32 10 1 * 5 behenoyl-pyrogallol 38 20 60 57072

Example U

A polyester blend coated with a mixture of silver and ferric soaps according to Example 3 except that 2 parts of tetrachlorophthalic anhydride per 100 parts of metal soap was used in the coating mixture and a coating weight of 6.1 * 5 g / m was further applied. parts of behenoylpyrogallol and 200 parts of cellulose acetate butyrate in 18,000 parts of methyl ethyl ketone with a coating weight of 2 * 76 g / m 2 after drying. The sheet is used to produce a transparent projection film from half-tone prints of a wire printing method by thermographic copying. The parts of the pattern are much more uniform in appearance than in the film of Example 1, and the colors of the pattern are gray rather than purple in the lighter areas.

Claims (7)

6 57072 A heat-sensitive sheet material comprising, as a thin layer, a heat-sensitive composition having a wide radiation flexibility on a support, the composition providing a visible image when heated to obtain an image, characterized in that the composition is a mixture of long chain fatty acid iron (III) and silver soaps, the amount of silver soap being from 10 to 80% by weight of the mixture, optionally a silver image toner and the phenol-coreactant of these soaps. A sheet-like material according to claim 1, characterized in that the layer contains a polymeric film-like binder and is supported by a transparent carrier film and that this sheet material is clear and transparent. Sheet material according to Claim 2, characterized in that approximately equal amounts of iron (III) and silver soaps are present. Sheet material according to Claim 3, characterized in that the iron (III) soap is iron (III) stearate, the silver soap is silver benate and the toner is phthalazinone. Sheet material according to Claim U, characterized in that the phenol-coreactant is behenoylpyrogallol, The sheet material according to claim 1, having a thin flexible substrate and a thin coating attached thereto, characterized in that it is a mixture of 10 to 80 parts by weight of long-chain fatty acid silver soap and 90 to 20 parts by weight of long-chain fatty acid iron, respectively. ) soap. A method of making a heat-sensitive copy sheet according to claim 1, characterized in that 10 to 80 parts by weight of long-chain fatty acid silver soap and 90 to 20 parts of long-chain fatty acid iron (III) are mixed with about 20 to 20 parts by weight of long-chain fatty acid with one part by weight of phthalazinone for every 100 parts by weight of silver soap, and that this mixture is applied to the substrate.